Your search keyword '"Ambystoma mexicanum genetics"' showing total 192 results

1. Tyrp1 is the mendelian determinant of the Axolotl (Ambystoma mexicanum) copper mutant.

Author

Cecil RF, Strohl L, Thomas MK, Schwartz JL, Timoshevskaya N, Smith JJ, and Voss SR

Subjects

Animals, Phenotype, Oxidoreductases genetics, Oxidoreductases metabolism, Melanins metabolism, Melanins genetics, Ambystoma mexicanum genetics, Copper metabolism, Polymorphism, Single Nucleotide, Mutation, Pigmentation genetics

Abstract

Several dozen Mendelian mutants have been discovered in axolotl (Ambystoma mexicanum) populations, including several that affect pigmentation. Four recessive mutants have been described in the scientific literature and genes for three of these have been identified. Here we describe and genetically dissect copper, a mutant with an albino-like phenotype known only from the pet trade. We performed a cross segregating copper and wildtype color phenotypes and used bulked segregant RNA-Seq to identify a region on chromosome 6 that was enriched for single-nucleotide polymorphisms (SNPs) between the color phenotypes. This region included Tyrosinase-like Protein 1 (Tyrp1), a melanin synthesis protein that when mutated, is associated with lighter than black melanin coloration in animal models and oculocutaneous albinism in humans. Inspection of RNA-Seq reads identified a single nucleotide deletion that is predicted to change the coding frame, introduce a premature stop codon in exon 6 and yield a truncated Tyrp1 protein in copper individuals. Using CRISPR-Cas9 editing, we show that wildtype Tyrp1 crispants exhibit copper pigmentation, thus confirming Tyrp1 as the copper locus. Our results suggest that commercial and hobbyist axolotl populations may harbor useful mutants for biological research., (© 2024. The Author(s).)

Published

2024

2. A chromatin code for limb segment identity in axolotl limb regeneration.

Author

Kawaguchi A, Wang J, Knapp D, Murawala P, Nowoshilow S, Masselink W, Taniguchi-Sugiura Y, Fei JF, and Tanaka EM

Subjects

Animals, Histones metabolism, Histones genetics, Gene Expression Regulation, Developmental genetics, Transcription Factors metabolism, Transcription Factors genetics, Regeneration genetics, Regeneration physiology, Extremities, Chromatin metabolism, Chromatin genetics, Ambystoma mexicanum genetics, Homeodomain Proteins metabolism, Homeodomain Proteins genetics

Abstract

The salamander limb correctly regenerates missing limb segments because connective tissue cells have segment-specific identities, termed "positional information". How positional information is molecularly encoded at the chromatin level has been unknown. Here, we performed genome-wide chromatin profiling in mature and regenerating axolotl limb connective tissue cells. We find segment-specific levels of histone H3K27me3 as the major positional mark, especially at limb homeoprotein gene loci but not their upstream regulators, constituting an intrinsic segment information code. During regeneration, regeneration-specific regulatory elements became active prior to the re-appearance of developmental regulatory elements. In the hand, the permissive chromatin state of the homeoprotein gene HoxA13 engages with the regeneration program bypassing the upper limb program. Comparison of regeneration regulatory elements with those found in other regenerative animals identified a core shared set of transcription factors, supporting an ancient, conserved regeneration program., Competing Interests: Declaration of interests E.M.T. is a member of the advisory board for Developmental Cell but did not participate in the editorial process of this manuscript., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

3. Sall4 regulates downstream patterning genes during limb regeneration.

Author

Erickson JR, Walker SE, Arenas Gomez CM, and Echeverri K

Subjects

Animals, Gene Expression Regulation, Developmental genetics, Amphibian Proteins genetics, Amphibian Proteins metabolism, Regeneration genetics, Regeneration physiology, Transcription Factors metabolism, Transcription Factors genetics, Extremities physiology, Extremities embryology, Ambystoma mexicanum genetics, Ambystoma mexicanum physiology, Body Patterning genetics

Abstract

Many salamanders can completely regenerate a fully functional limb. Limb regeneration is a carefully coordinated process involving several defined stages. One key event during the regeneration process is the patterning of the blastema to inform cells of what they must differentiate into. Although it is known that many genes involved in the initial development of the limb are re-used during regeneration, the exact molecular circuitry involved in this process is not fully understood. Several large-scale transcriptional profiling studies of axolotl limb regeneration have identified many transcription factors that are up-regulated after limb amputation. Sall4 is a transcription factor that has been identified to play essential roles in maintaining cells in an undifferentiated state during development and also plays a unique role in limb development. Inactivation of Sall4 during limb bud development results in defects in anterior-posterior patterning of the limb. Sall4 has been found to be up-regulated during limb regeneration in both Xenopus and salamanders, but to date it function has been untested. We confirmed that Sall4 is up-regulated during limb regeneration in the axolotl using qRT-PCR and identified that it is present in the skin cells and also in cells within the blastema. Using CRISPR technology we microinjected gRNAs specific for Sall4 complexed with cas9 protein into the blastema to specifically knockout Sall4 in blastema cells only. This resulted in limb regenerate defects, including missing digits, fusion of digit elements, and defects in the radius and ulna. This suggests that during regeneration Sall4 may play a similar role in regulating the specification of anterior-proximal skeletal elements., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

4. Identification and Analysis of Axolotl Homologs for Proteins Implicated in Human Neurodegenerative Proteinopathies.

Author

James LM, Strickland Z, Lopez N, Whited JL, Maden M, and Lewis J

Subjects

Adult, Animals, Humans, Ambystoma mexicanum genetics, Ambystoma mexicanum metabolism, Amyloid Precursor Protein Secretases, Aspartic Acid Endopeptidases, tau Proteins genetics, Alzheimer Disease genetics, Neurodegenerative Diseases genetics, Proteostasis Deficiencies

Abstract

Neurodegenerative proteinopathies such as Alzheimer's Disease are characterized by abnormal protein aggregation and neurodegeneration. Neuroresilience or regenerative strategies to prevent neurodegeneration, preserve function, or restore lost neurons may have the potential to combat human proteinopathies; however, the adult human brain possesses a limited capacity to replace lost neurons. In contrast, axolotls ( Ambystoma mexicanum ) show robust brain regeneration. To determine whether axolotls may help identify potential neuroresilience or regenerative strategies in humans, we first interrogated whether axolotls express putative proteins homologous to human proteins associated with neurodegenerative diseases. We compared the homology between human and axolotl proteins implicated in human proteinopathies and found that axolotls encode proteins highly similar to human microtubule-binding protein tau (tau), amyloid precursor protein (APP), and β-secretase 1 (BACE1), which are critically involved in human proteinopathies like Alzheimer's Disease. We then tested monoclonal Tau and BACE1 antibodies previously used in human and rodent neurodegenerative disease studies using immunohistochemistry and western blotting to validate the homology for these proteins. These studies suggest that axolotls may prove useful in studying the role of these proteins in disease within the context of neuroresilience and repair.

Published

2024

5. Transcriptome Profiling after Early Spinal Cord Injury in the Axolotl and Its Comparison with Rodent Animal Models through RNA-Seq Data Analysis.

Author

González-Orozco JC, Escobedo-Avila I, and Velasco I

Subjects

Humans, Animals, Rats, Mice, RNA-Seq, Rodentia genetics, Gene Expression Profiling, Models, Animal, Ambystoma mexicanum genetics, Spinal Cord Injuries genetics, Spinal Cord Injuries metabolism

Abstract

Background: Traumatic spinal cord injury (SCI) is a disabling condition that affects millions of people around the world. Currently, no clinical treatment can restore spinal cord function. Comparison of molecular responses in regenerating to non-regenerating vertebrates can shed light on neural restoration. The axolotl ( Ambystoma mexicanum ) is an amphibian that regenerates regions of the brain or spinal cord after damage., Methods: In this study, we compared the transcriptomes after SCI at acute (1-2 days after SCI) and sub-acute (6-7 days post-SCI) periods through the analysis of RNA-seq public datasets from axolotl and non-regenerating rodents., Results: Genes related to wound healing and immune responses were upregulated in axolotls, rats, and mice after SCI; however, the immune-related processes were more prevalent in rodents. In the acute phase of SCI in the axolotl, the molecular pathways and genes associated with early development were upregulated, while processes related to neuronal function were downregulated. Importantly, the downregulation of processes related to sensorial and motor functions was observed only in rodents. This analysis also revealed that genes related to pluripotency, cytoskeleton rearrangement, and transposable elements (e.g., Sox2 , Krt5 , and LOC100130764 ) were among the most upregulated in the axolotl. Finally, gene regulatory networks in axolotls revealed the early activation of genes related to neurogenesis, including Atf3/4 and Foxa2 ., Conclusions: Immune-related processes are upregulated shortly after SCI in axolotls and rodents; however, a strong immune response is more noticeable in rodents. Genes related to early development and neurogenesis are upregulated beginning in the acute stage of SCI in axolotls, while the loss of motor and sensory functions is detected only in rodents during the sub-acute period of SCI. The approach employed in this study might be useful for designing and establishing regenerative therapies after SCI in mammals, including humans.

Published

2023

6. The Dynamic Landscapes of Circular RNAs in Axolotl, a Regenerative Medicine Model, with Implications for Early Phase of Limb Regeneration.

Author

Demircan T and Süzek BE

Subjects

Animals, Humans, RNA genetics, RNA metabolism, Ambystoma mexicanum genetics, Ambystoma mexicanum metabolism, Regenerative Medicine, Sequence Analysis, RNA methods, RNA, Circular genetics, MicroRNAs genetics

Abstract

Circular RNAs (circRNAs) are of relevance to regenerative medicine and play crucial roles in post-transcriptional and translational regulation of biological processes. circRNAs are a class of RNA molecules that are formed through a unique splicing process, resulting in a covalently closed-loop structure. Recent advancements in RNA sequencing technologies and specialized computational tools have facilitated the identification and functional characterization of circRNAs. These molecules are known to exhibit stability, developmental regulation, and specific expression patterns in different tissues and cell types across various organisms. However, our understanding of circRNA expression and putative function in model organisms for regeneration is limited. In this context, this study reports, for the first time, on the repertoire of circRNAs in axolotl, a widely used model organism for regeneration. We generated RNA-seq data from intact limb, wound, and blastema tissues of axolotl during limb regeneration. The analysis revealed the presence of 35,956 putative axolotl circRNAs, among which 5331 unique circRNAs exhibited orthology with human circRNAs. In silico data analysis underlined the potential roles of axolotl circRNAs in cell cycle, cell death, and cell senescence-related pathways during limb regeneration, suggesting the participation of circRNAs in regulation of diverse functions pertinent to regenerative medicine. These new observations help advance our understanding of the dynamic landscape of axolotl circRNAs, and by extension, inform future regenerative medicine research and innovation that harness this model organism.

Published

2023

7. A scATAC-seq atlas of chromatin accessibility in axolotl brain regions.

Author

Feng W, Liu S, Deng Q, Fu S, Yang Y, Dai X, Wang S, Wang Y, Liu Y, Lin X, Pan X, Hao S, Yuan Y, Gu Y, Zhang X, Li H, Liu L, Liu C, Fei JF, and Wei X

Subjects

Animals, Ascomycota, Learning, Mesencephalon, Single-Cell Gene Expression Analysis, Ambystoma mexicanum genetics, Brain, Chromatin

Abstract

Axolotl (Ambystoma mexicanum) is an excellent model for investigating regeneration, the interaction between regenerative and developmental processes, comparative genomics, and evolution. The brain, which serves as the material basis of consciousness, learning, memory, and behavior, is the most complex and advanced organ in axolotl. The modulation of transcription factors is a crucial aspect in determining the function of diverse regions within the brain. There is, however, no comprehensive understanding of the gene regulatory network of axolotl brain regions. Here, we utilized single-cell ATAC sequencing to generate the chromatin accessibility landscapes of 81,199 cells from the olfactory bulb, telencephalon, diencephalon and mesencephalon, hypothalamus and pituitary, and the rhombencephalon. Based on these data, we identified key transcription factors specific to distinct cell types and compared cell type functions across brain regions. Our results provide a foundation for comprehensive analysis of gene regulatory programs, which are valuable for future studies of axolotl brain development, regeneration, and evolution, as well as on the mechanisms underlying cell-type diversity in vertebrate brains., (© 2023. Springer Nature Limited.)

Published

2023

8. Downregulation of Yap1 during limb regeneration results in defective bone formation in axolotl.

Author

Bay S, Öztürk G, Emekli N, and Demircan T

Subjects

Animals, Down-Regulation, Chromatography, Liquid, Signal Transduction, Tandem Mass Spectrometry, Transcription Factors genetics, Transcription Factors metabolism, Adaptor Proteins, Signal Transducing metabolism, Ambystoma mexicanum genetics, Osteogenesis

Abstract

The Hippo pathway plays an imperative role in cellular processes such as differentiation, regeneration, cell migration, organ growth, apoptosis, and cell cycle. Transcription coregulator component of Hippo pathway, YAP1, promotes transcription of genes involved in cell proliferation, migration, differentiation, and suppressing apoptosis. However, its role in epimorphic regeneration has not been fully explored. The axolotl is a well-established model organism for developmental biology and regeneration studies. By exploiting its remarkable regenerative capacity, we investigated the role of Yap1 in the early blastema stage of limb regeneration. Depleting Yap1 using gene-specific morpholinos attenuated the competence of axolotl limb regeneration evident in bone formation defects. To explore the affected downstream pathways from Yap1 down-regulation, the gene expression profile was examined by employing LC-MS/MS technology. Based on the generated data, we provided a new layer of evidence on the putative roles of increased protease inhibition and immune system activities and altered ECM composition in diminished bone formation capacity during axolotl limb regeneration upon Yap1 deficiency. We believe that new insights into the roles of the Hippo pathway in complex structure regeneration were granted in this study., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

9. NANOG is required to establish the competence for germ-layer differentiation in the basal tetrapod axolotl.

Author

Simpson LA, Crowley D, Forey T, Acosta H, Ferjentsik Z, Chatfield J, Payne A, Simpson BS, Redwood C, Dixon JE, Holmes N, Sang F, Alberio R, Loose M, and Johnson AD

Subjects

Animals, Ambystoma mexicanum genetics, Ambystoma mexicanum metabolism, Zebrafish genetics, Cell Differentiation, Nanog Homeobox Protein genetics, Nanog Homeobox Protein metabolism, Gene Expression Regulation, Developmental, Homeodomain Proteins metabolism, Pluripotent Stem Cells

Abstract

Pluripotency defines the unlimited potential of individual cells of vertebrate embryos, from which all adult somatic cells and germ cells are derived. Understanding how the programming of pluripotency evolved has been obscured in part by a lack of data from lower vertebrates; in model systems such as frogs and zebrafish, the function of the pluripotency genes NANOG and POU5F1 have diverged. Here, we investigated how the axolotl ortholog of NANOG programs pluripotency during development. Axolotl NANOG is absolutely required for gastrulation and germ-layer commitment. We show that in axolotl primitive ectoderm (animal caps; ACs) NANOG and NODAL activity, as well as the epigenetic modifying enzyme DPY30, are required for the mass deposition of H3K4me3 in pluripotent chromatin. We also demonstrate that all 3 protein activities are required for ACs to establish the competency to differentiate toward mesoderm. Our results suggest the ancient function of NANOG may be establishing the competence for lineage differentiation in early cells. These observations provide insights into embryonic development in the tetrapod ancestor from which terrestrial vertebrates evolved., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Simpson et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

10. Leukocyte Tyrosine Kinase ( Ltk ) Is the Mendelian Determinant of the Axolotl Melanoid Color Variant.

Author

Kabangu M, Cecil R, Strohl L 2nd, Timoshevskaya N, Smith JJ, and Voss SR

Subjects

Animals, Melanophores metabolism, Cell Differentiation genetics, Leukocytes, Ambystoma mexicanum genetics, Ambystoma mexicanum metabolism, Zebrafish genetics

Abstract

The great diversity of color patterns observed among amphibians is largely explained by the differentiation of relatively few pigment cell types during development. Mexican axolotls present a variety of color phenotypes that span the continuum from leucistic to highly melanistic. The melanoid axolotl is a Mendelian variant characterized by large numbers of melanophores, proportionally fewer xanthophores, and no iridophores. Early studies of melanoid were influential in developing the single-origin hypothesis of pigment cell development, wherein it has been proposed that all three pigment cell types derive from a common progenitor cell, with pigment metabolites playing potential roles in directing the development of organelles that define different pigment cell types. Specifically, these studies identified xanthine dehydrogenase (XDH) activity as a mechanism for the permissive differentiation of melanophores at the expense of xanthophores and iridophores. We used bulked segregant RNA-Seq to screen the axolotl genome for melanoid candidate genes and identify the associated locus. Dissimilar frequencies of single-nucleotide polymorphisms were identified between pooled RNA samples of wild-type and melanoid siblings for a region on chromosome 14q. This region contains gephyrin ( Gphn ), an enzyme that catalyzes the synthesis of the molybdenum cofactor that is required for XDH activity, and leukocyte tyrosine kinase ( Ltk ), a cell surface signaling receptor that is required for iridophore differentiation in zebrafish. Wild-type Ltk crispants present similar pigment phenotypes to melanoid , strongly implicating Ltk as the melanoid locus. In concert with recent findings in zebrafish, our results support the idea of direct fate specification of pigment cells and, more generally, the single-origin hypothesis of pigment cell development.

Published

2023

11. Characterization of immunoglobulin loci in the gigantic genome of Ambystoma mexicanum .

Author

Martinez-Barnetche J, Godoy-Lozano EE, Saint Remy-Hernández S, Pacheco-Olvera DL, Téllez-Sosa J, Valdovinos-Torres H, Pastelin-Palacios R, Mena H, Zambrano L, and López-Macías C

Subjects

Animals, Genome, Genomics, Ambystoma mexicanum genetics, Immunoglobulins genetics

Abstract

Background: The axolotl, Ambystoma mexicanum is a unique biological model for complete tissue regeneration. Is a neotenic endangered species and is highly susceptible to environmental stress, including infectious disease. In contrast to other amphibians, the axolotl is particularly vulnerable to certain viral infections. Like other salamanders, the axolotl genome is one of the largest (32 Gb) and the impact of genome size on Ig loci architecture is unknown. To better understand the immune response in axolotl, we aimed to characterize the immunoglobulin loci of A. mexicanum and compare it with other model vertebrates., Methods: The most recently published genome sequence of A. mexicanum (V6) was used for alignment-based annotation and manual curation using previously described axolotl Ig sequences or reference sequences from other vertebrates. Gene models were further curated using A. mexicanum spleen RNA-seq data. Human, Xenopus tropicalis , Danio rerio (zebrafish), and eight tetrapod reference genomes were used for comparison., Results: Canonical A. mexicanum heavy chain (IGH), lambda (IGL), sigma (IGS), and the putative surrogate light chain (SLC) loci were identified. No kappa locus was found. More than half of the IGHV genes and the IGHF gene are pseudogenes and there is no clan I IGHV genes. Although the IGH locus size is proportional to genome size, we found local size restriction in the IGHM gene and the V gene intergenic distances. In addition, there were V genes with abnormally large V-intron sizes, which correlated with loss of gene functionality., Conclusion: The A. mexicanum immunoglobulin loci share the same general genome architecture as most studied tetrapods. Consistent with its large genome, Ig loci are larger; however, local size restrictions indicate evolutionary constraints likely to be imposed by high transcriptional demand of certain Ig genes, as well as the V(D)J recombination over very long genomic distance ranges. The A. mexicanum has undergone an extensive process of Ig gene loss which partially explains a reduced potential repertoire diversity that may contribute to its impaired antibody response., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Martinez-Barnetche, Godoy-Lozano, Saint Remy-Hernández, Pacheco-Olvera, Téllez-Sosa, Valdovinos-Torres, Pastelin-Palacios, Mena, Zambrano and López-Macías.)

Published

2023

12. Artificial Insemination in Axolotl.

Author

Taniguchi-Sugiura Y and Tanaka EM

Subjects

Humans, Animals, Male, Female, Cloaca, Breeding, Insemination, Artificial veterinary, Ambystoma mexicanum genetics, Semen

Abstract

In axolotls (Ambystoma mexicanum), fertilization takes place internally. After courtship, the male axolotl deposits spermatophores, which the female takes up into her cloaca in order to fertilize eggs internally. The success of axolotl breedings is subject to several poorly understood factors including age, pairing, and genotype. In some cases, individuals are unable to breed naturally despite having significant scientific value. Assisted reproductive technologies represent one approach to maintaining stocks of such individuals, as well as supplementing natural breedings of laboratory stocks.Here, we describe a protocol for artificial insemination--an assisted reproductive technology in which sperm is extracted from a male and transferred into the female cloaca, thus mimicking natural fertilization in axolotls. We believe that this simple method can be applied to other salamander species that have internal fertilization and also help restore endangered wild populations., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

13. Fluorescence In Situ Hybridization of DNA Probes on Mitotic Chromosomes of the Mexican Axolotl.

Author

Keinath M and Timoshevskiy V

Subjects

Animals, In Situ Hybridization, Fluorescence methods, Interphase genetics, DNA Probes genetics, DNA genetics, RNA, Ambystoma mexicanum genetics, Chromosomes genetics

Abstract

Fluorescence in situ hybridization (FISH) is used extensively for visual localization of specific DNA fragments (and RNA fragments) in broad applications on chromosomes or nuclei at any stage of the cell cycle: metaphase, anaphase, or interphase. The cytogenetic slides that serve as a target for the labeled DNA probe might be prepared using any approach suitable for obtaining cells with appropriate morphology for imaging and analysis. In this chapter, we focus on the application of molecular cytogenetic methods such as DNA labeling, slide preparation, and in situ hybridization related to cells from Mexican axolotl., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

14. Axolotl Transgenesis via Injection of I-SceI Meganuclease or Tol2 Transposon System.

Author

Schuez M and Sandoval-Guzmán T

Subjects

Animals, Gene Transfer Techniques, DNA genetics, Injections, Ambystoma mexicanum genetics, Ambystoma mexicanum metabolism, Deoxyribonucleases, Type II Site-Specific metabolism

Abstract

The axolotl (Ambystoma mexicanum ) has been widely used as an animal model for studying development and regeneration. In recent decades, the use of genetic engineering to alter gene expression has advanced our knowledge on the fundamental molecular and cellular mechanisms, pointing us to potential therapeutic targets. We present a detailed, step-by-step protocol for axolotl transgenesis using either I-SceI meganuclease or the mini Tol2 transposon system, by injection of purified DNA into one-cell stage eggs. We add useful tips on the site of injection and the viability of the eggs., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

15. A Practical Guide for CRISPR-Cas9-Induced Mutations in Axolotls.

Author

Sousounis K, Courtemanche K, and Whited JL

Subjects

Animals, Ambystoma mexicanum genetics, Genome, Mutation, RNA, Guide, CRISPR-Cas Systems genetics, CRISPR-Cas Systems genetics, Gene Editing

Abstract

Clustered regularly interspaced short palindromic repeats (CRISPR) is a powerful tool that enables editing of the axolotl genome. In this chapter, we will cover how to retrieve gene sequences, confirm annotation, design CRISPR targets, analyze indels, and screen for Crispant axolotls. This is a comprehensive guide on how to use CRISPR on your favorite gene and gain insights into its function., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

16. Bead Implantation and Delivery of Exogenous Growth Factors.

Author

Kashimoto R, Furukawa S, Yamamoto S, and Satoh A

Subjects

Animals, Humans, Intercellular Signaling Peptides and Proteins, Extremities physiology, Ambystoma mexicanum genetics

Abstract

Genetic methods in axolotls (Ambystoma mexicanum) remain in their infancy which has hampered the study of limb regeneration. There is much room for advancement, especially with respect to spatiotemporal regulation of gene expression. Secreted growth factors play a major role in each stage of regeneration. The use of slow-release beads is one of the most effective methods to control the spatiotemporal expression of secretory gene products. The topical administration of secreted factors by slow-release beads may also prove effective for future applications in non-regenerative animals and for medical applications in humans, in which genetic methods are not available. In this chapter, we describe a methodology for using and implanting slow-release beads to deliver exogenous growth factors to salamanders., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

17. COMET Assay for Detection of DNA Damage During Axolotl Tail Regeneration.

Author

Carbonell B, Álvarez J, Santa-González GA, and Delgado JP

Subjects

Animals, Comet Assay methods, Sepharose, Electrophoresis, Ambystoma mexicanum genetics, DNA Damage

Abstract

The purpose of this chapter is to evaluate DNA damage during axolotl tail regeneration using an alkaline comet assay. Our method details the isolation of cells from regenerating and non-regenerating tissues and the isolation of peripheral blood for single-cell gel electrophoresis. Also, we detail each of the steps for the development of the comet assay technique which includes mounting the isolated cells on an agarose matrix, alkaline electrophoresis, and DNA damage detection., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

18. Applying a Knock-In Strategy to Create Reporter-Tagged Knockout Alleles in Axolotls.

Author

Wang L, Zeng YY, Liu Y, and Fei JF

Subjects

Animals, Alleles, Gene Knock-In Techniques, Gene Knockout Techniques, Ambystoma mexicanum genetics, CRISPR-Cas Systems genetics

Abstract

Tetrapod species axolotls exhibit the powerful capacity to fully regenerate their tail and limbs upon injury, hence serving as an excellent model organism in regenerative biology research. Developing proper molecular and genetic tools in axolotls is an absolute necessity for deep dissection of tissue regeneration mechanisms. Previously, CRISPR-/Cas9-based knockout and targeted gene knock-in approaches have been established in axolotls, allowing genetically deciphering gene function, labeling, and tracing particular types of cells. Here, we further extend the CRISPR/Cas9 technology application and describe a method to create reporter-tagged knockout allele in axolotls. This method combines gene knockout and knock-in and achieves loss of function of a given gene and simultaneous labeling of cells expressing this particular gene, that allows identification, tracking of the "knocking out" cells. Our method offers a useful gene function analysis tool to the field of axolotl developmental and regenerative research., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

19. Hybridization Chain Reaction Fluorescence In Situ Hybridization (HCR-FISH) in Ambystoma mexicanum Tissue.

Author

Lovely AM, Duerr TJ, Stein DF, Mun ET, and Monaghan JR

Subjects

Animals, In Situ Hybridization, Fluorescence methods, RNA, Messenger genetics, Extremities, RNA, Ambystoma mexicanum genetics, Fluorescent Dyes

Abstract

In situ hybridization is a standard procedure for visualizing mRNA transcripts in tissues. The recent adoption of fluorescent probes and new signal amplification methods have facilitated multiplexed RNA imaging in tissue sections and whole tissues. Here we present protocols for multiplexed hybridization chain reaction fluorescence in situ hybridization (HCR-FISH) staining, imaging, cell segmentation, and mRNA quantification in regenerating axolotl tissue sections. We also present a protocol for whole-mount staining and imaging of developing axolotl limbs., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

20. Establishing an Efficient Electroporation-Based Method to Manipulate Target Gene Expression in the Axolotl Brain.

Author

Fu S, Peng C, Zeng YY, Qiu Y, Liu Y, and Fei JF

Subjects

Animals, Electroporation, Neurons metabolism, CRISPR-Associated Protein 9 genetics, Gene Expression, Ambystoma mexicanum genetics, Ambystoma mexicanum metabolism, Brain metabolism

Abstract

The tetrapod salamander species axolotl ( Ambystoma mexicanum ) is capable of regenerating injured brain. For better understanding the mechanisms of brain regeneration, it is very necessary to establish a rapid and efficient gain-of-function and loss-of-function approaches to study gene function in the axolotl brain. Here, we establish and optimize an electroporation-based method to overexpress or knockout/knockdown target gene in ependymal glial cells (EGCs) in the axolotl telencephalon. By orientating the electrodes, we were able to achieve specific expression of EGFP in EGCs located in dorsal, ventral, medial, or lateral ventricular zones. We then studied the role of Cdc42 in brain regeneration by introducing Cdc42 into EGCs through electroporation, followed by brain injury. Our findings showed that overexpression of Cdc42 in EGCs did not significantly affect EGC proliferation and production of newly born neurons, but it disrupted their apical polarity, as indicated by the loss of the ZO-1 tight junction marker. This disruption led to a ventricular accumulation of newly born neurons, which are failed to migrate into the neuronal layer where they could mature, thus resulted in a delayed brain regeneration phenotype. Furthermore, when electroporating CAS9-gRNA protein complexes against TnC ( Tenascin-C ) into EGCs of the brain, we achieved an efficient knockdown of TnC . In the electroporation-targeted area, TnC expression is dramatically reduced at both mRNA and protein levels. Overall, this study established a rapid and efficient electroporation-based gene manipulation approach allowing for investigation of gene function in the process of axolotl brain regeneration.

Published

2023

21. The Use of Small Molecules to Dissect Developmental and Regenerative Processes in Axolotls.

Author

Roy S

Subjects

Animals, Ambystoma mexicanum genetics, Signal Transduction

Abstract

The axolotl provides an interesting model organism to study different biological processes that are of interest to basic biological sciences and biomedical research. Although axolotls have been in labs for close to 160 years, genetic manipulations still represent a major challenge for most labs. The use of small molecules to target specific signaling pathways allows studies to proceed in animals that are difficult to manipulate genetically. This chapter provides a description of how we administer these chemicals to axolotls., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

22. Establishing a New Research Axolotl Colony.

Author

Yandulskaya AS and Monaghan JR

Subjects

Animals, Ambystoma mexicanum genetics

Abstract

The field of regenerative biology has taken a keen interest in the Mexican axolotl (Ambystoma mexicanum) over the past few decades, as this salamander successfully regenerates amputated limbs and injured body parts. Recent progress in research tool development has also made possible axolotl genetic manipulation and single-cell analysis, which will help understand the molecular mechanisms of complex tissue regeneration. To support the growing popularity of this model, we describe how to set up a new axolotl housing facility at a research laboratory. We also review husbandry practices for raising axolotls and using them in biological research, with a focus on diet, water quality, breeding, and anesthesia., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

23. Baculovirus Production and Infection in Axolotls.

Author

Murawala P, Oliveira CR, Okulski H, Yun MH, and Tanaka EM

Subjects

Animals, Animals, Genetically Modified, Urodela, Ambystoma mexicanum genetics, Baculoviridae genetics

Abstract

Salamanders have served as an excellent model for developmental and tissue regeneration studies. While transgenic approaches are available for various salamander species, their long generation time and expensive maintenance have driven the development of alternative gene delivery methods for functional studies. We have previously developed pseudotyped baculovirus (BV) as a tool for gene delivery in the axolotl (Oliveira et al. Dev Biol 433(2):262-275, 2018). Since its initial conception, we have refined our protocol of BV production and usage in salamander models. In this chapter, we describe a detailed and versatile protocol for BV-mediated transduction in urodeles., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

24. Construction of the axolotl cell landscape using combinatorial hybridization sequencing at single-cell resolution.

Author

Ye F, Zhang G, E W, Chen H, Yu C, Yang L, Fu Y, Li J, Fu S, Sun Z, Fei L, Guo Q, Wang J, Xiao Y, Wang X, Zhang P, Ma L, Ge D, Xu S, Caballero-Pérez J, Cruz-Ramírez A, Zhou Y, Chen M, Fei JF, Han X, and Guo G

Subjects

Animals, Gene Expression Profiling, Nucleic Acid Hybridization, Ambystoma mexicanum genetics, Metamorphosis, Biological genetics

Abstract

The Mexican axolotl (Ambystoma mexicanum) is a well-established tetrapod model for regeneration and developmental studies. Remarkably, neotenic axolotls may undergo metamorphosis, a process that triggers many dramatic changes in diverse organs, accompanied by gradually decline of their regeneration capacity and lifespan. However, the molecular regulation and cellular changes in neotenic and metamorphosed axolotls are still poorly investigated. Here, we develop a single-cell sequencing method based on combinatorial hybridization to generate a tissue-based transcriptomic landscape of the neotenic and metamorphosed axolotls. We perform gene expression profiling of over 1 million single cells across 19 tissues to construct the first adult axolotl cell landscape. Comparison of single-cell transcriptomes between the tissues of neotenic and metamorphosed axolotls reveal the heterogeneity of non-immune parenchymal cells in different tissues and established their regulatory network. Furthermore, we describe dynamic gene expression patterns during limb development in neotenic axolotls. This system-level single-cell analysis of molecular characteristics in neotenic and metamorphosed axolotls, serves as a resource to explore the molecular identity of the axolotl and facilitates better understanding of metamorphosis., (© 2022. The Author(s).)

Published

2022

25. Gene and transgenics nomenclature for the laboratory axolotl-Ambystoma mexicanum.

Author

Nowoshilow S, Fei JF, Voss SR, Tanaka EM, and Murawala P

Subjects

Animals, Animals, Genetically Modified, Ambystoma mexicanum genetics, Wound Healing

Abstract

The laboratory axolotl (Ambystoma mexicanum) is widely used in biological research. Recent advancements in genetic and molecular toolkits are greatly accelerating the work using axolotl, especially in the area of tissue regeneration. At this juncture, there is a critical need to establish gene and transgenic nomenclature to ensure uniformity in axolotl research. Here, we propose guidelines for genetic nomenclature when working with the axolotl., (© 2021 The Authors. Developmental Dynamics published by Wiley Periodicals LLC on behalf of American Association of Anatomists.)

Published

2022

26. Canonical Wnt signaling and the regulation of divergent mesenchymal Fgf8 expression in axolotl limb development and regeneration.

Author

Glotzer GL, Tardivo P, and Tanaka EM

Subjects

Animals, Chickens genetics, Extremities physiology, Fibroblast Growth Factor 8 genetics, Fibroblast Growth Factor 8 metabolism, Fibroblast Growth Factors metabolism, Gene Expression Regulation, Developmental, In Situ Hybridization, Fluorescence, Ligands, Vertebrates genetics, Ambystoma mexicanum genetics, Wnt Signaling Pathway

Abstract

The expression of fibroblast growth factors (Fgf) ligands in a specialized epithelial compartment, the Apical Ectodermal Ridge (AER), is a conserved feature of limb development across vertebrate species. In vertebrates, Fgf 4 , 8 , 9 , and 17 are all expressed in the AER. An exception to this paradigm is the salamander (axolotl) developing and regenerating limb, where key Fgf ligands are expressed in the mesenchyme. The mesenchymal expression of Amex. Fgf8 in axolotl has been suggested to be critical for regeneration. To date, there is little knowledge regarding what controls Amex. Fgf8 expression in the axolotl limb mesenchyme. A large body of mouse and chick studies have defined a set of transcription factors and canonical Wnt signaling as the main regulators of epidermal Fgf8 expression in these organisms. In this study, we address the hypothesis that alterations to one or more of these components during evolution has resulted in mesenchymal Amex. Fgf8 expression in the axolotl. To sensitively quantify gene expression with spatial precision, we combined optical clearing of whole-mount axolotl limb tissue with single molecule fluorescent in situ hybridization and a semiautomated quantification pipeline. Several candidate upstream components were found expressed in the axolotl ectoderm, indicating that they are not direct regulators of Amex. Fgf8 expression. We found that Amex. Wnt3a is expressed in axolotl limb epidermis, similar to chicken and mouse. However, unlike in amniotes, Wnt target genes are activated preferentially in limb mesenchyme rather than in epidermis. Inhibition and activation of Wnt signaling results in downregulation and upregulation of mesenchymal Amex. Fgf8 expression, respectively. These results implicate a shift in tissue responsiveness to canonical Wnt signaling from epidermis to mesenchyme as one step contributing to the unique mesenchymal Amex. Fgf8 expression seen in the axolotl., Competing Interests: GG, PT, ET No competing interests declared, (© 2022, Glotzer, Tardivo et al.)

Published

2022

27. An Identification and Characterization of the Axolotl ( Ambystoma mexicanum, Amex ) Telomerase Reverse Transcriptase (Amex TERT).

Author

Springhetti S, Bucan V, Liebsch C, Lazaridis A, Vogt PM, and Strauß S

Subjects

Animals, Base Sequence, Humans, Regeneration genetics, Telomere metabolism, Vertebrates genetics, Ambystoma mexicanum genetics, Ambystoma mexicanum metabolism, Telomerase genetics, Telomerase metabolism

Abstract

The Mexican axolotl is one of the few vertebrates that is able to replace its lost body parts during lifespan. Due to its remarkable regenerative abilities, the axolotl emerged as a model organism especially for limb regeneration. Telomeres and the telomerase enzyme are crucial for regeneration and protection against aging processes and degenerating diseases. Despite its relevance for regeneration, the axolotl telomerase and telomere length have not yet been investigated. Therefore, in the present paper, we reveal the sequence of the axolotl telomerase reverse transcriptase gene ( Tert ) and protein (TERT). Multiple sequence alignment (MSA) showed the known conserved RT- and TERT-specific motifs and residues found in other TERTs. In addition, we establish methods to determine the Tert expression (RT-PCR) and telomerase activity (Q-TRAP) of adult axolotl and blastema tissues. We found that both differentiated forelimb tissue and regenerating blastema tissue express Tert and show telomerase activity. Furthermore, blastema tissue appears to exhibit a higher Tert expression and telomerase activity. The presence of active telomerase in adult somatic cells is a decisive difference to somatic cells of non-regenerating vertebrates, such as humans. These findings indicate that telomere biology may play a key role in the regenerative abilities of cells.

Published

2022

28. The Axolotl's journey to the modern molecular era.

Author

Echeverri K, Fei J, and Tanaka EM

Subjects

Animals, Humans, Phenotype, Ambystoma mexicanum genetics

Abstract

The salamander Ambystoma mexicanum, commonly called "the axolotl" has a long, illustrious history as a model organism, perhaps with one of the longest track records as a laboratory-bred vertebrate, yet it also holds a prominent place among the emerging model organisms. Or rather it is by now an "emerged" model organism, boasting a full cohort molecular genetic tools that allows an expanding community of researchers in the field to explore the remarkable traits of this animal including regeneration, at cellular and molecular precision-which had been a dream for researchers over the years. This chapter describes the journey to this status, that could be helpful for those developing their respective animal or plant models., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

29. SpecHap: a diploid phasing algorithm based on spectral graph theory.

Author

Yu Y, Chen L, Miao X, and Li SC

Subjects

Animals, Benchmarking, Datasets as Topic, Diploidy, Haplotypes, Humans, Nanopores, Time Factors, Algorithms, Ambystoma mexicanum genetics, Genome, High-Throughput Nucleotide Sequencing statistics & numerical data, Sequence Analysis, DNA methods, Whole Genome Sequencing statistics & numerical data

Abstract

Haplotype phasing plays an important role in understanding the genetic data of diploid eukaryotic organisms. Different sequencing technologies (such as next-generation sequencing or third-generation sequencing) produce various genetic data that require haplotype assembly. Although multiple diploid haplotype phasing algorithms exist, only a few will work equally well across all sequencing technologies. In this work, we propose SpecHap, a novel haplotype assembly tool that leverages spectral graph theory. On both in silico and whole-genome sequencing datasets, SpecHap consumed less memory and required less CPU time, yet achieved comparable accuracy with state-of-art methods across all the test instances, which comprises sequencing data from next-generation sequencing, linked-reads, high-throughput chromosome conformation capture, PacBio single-molecule real-time, and Oxford Nanopore long-reads. Furthermore, SpecHap successfully phased an individual Ambystoma mexicanum, a species with gigantic diploid genomes, within 6 CPU hours and 945MB peak memory usage, while other tools failed to yield results either due to memory overflow (40GB) or time limit exceeded (5 days). Our results demonstrated that SpecHap is scalable, efficient, and accurate for diploid phasing across many sequencing platforms., (© The Author(s) 2021. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2021

30. The rax homeobox gene is mutated in the eyeless axolotl, Ambystoma mexicanum.

Author

Davis ES, Voss G, Miesfeld JB, Zarate-Sanchez J, Voss SR, and Glaser T

Subjects

Ambystoma mexicanum metabolism, Animals, Embryonic Development genetics, Eye Proteins metabolism, Gene Expression Regulation, Developmental, Homeodomain Proteins metabolism, Transcription Factors metabolism, Ambystoma mexicanum genetics, Eye Proteins genetics, Homeodomain Proteins genetics, Mutation, Transcription Factors genetics

Abstract

Background: Vertebrate eye formation requires coordinated inductive interactions between different embryonic tissue layers, first described in amphibians. A network of transcription factors and signaling molecules controls these steps, with mutations causing severe ocular, neuronal, and craniofacial defects. In eyeless mutant axolotls, eye morphogenesis arrests at the optic vesicle stage, before lens induction, and development of ventral forebrain structures is disrupted., Results: We identified a 5-bp deletion in the rax (retina and anterior neural fold homeobox) gene, which was tightly linked to the recessive eyeless (e) axolotl locus in an F2 cross. This frameshift mutation, in exon 2, truncates RAX protein within the homeodomain (P154fs35X). Quantitative RNA analysis shows that mutant and wild-type rax transcripts are equally abundant in E/e embryos. Translation appears to initiate from dual start codons, via leaky ribosome scanning, a conserved feature among gnathostome RAX proteins. Previous data show rax is expressed in the optic vesicle and diencephalon, deeply conserved among metazoans, and required for eye formation in other species., Conclusion: The eyeless axolotl mutation is a null allele in the rax homeobox gene, with primary defects in neural ectoderm, including the retinal and hypothalamic primordia., (© 2020 Wiley Periodicals LLC.)

Published

2021

31. Large-scale variation in single nucleotide polymorphism density within the laboratory axolotl (Ambystoma mexicanum).

Author

Timoshevskaya N, Voss SR, Labianca CN, High CR, and Smith JJ

Subjects

Animals, Mutation, Ambystoma mexicanum genetics, Biological Variation, Population, Genome, Polymorphism, Single Nucleotide

Abstract

Background: Recent efforts to assemble and analyze the Ambystoma mexicanum genome have dramatically improved the potential to develop molecular tools and pursue genome-wide analyses of genetic variation., Results: To better resolve the distribution and origins of genetic variation with A mexicanum, we compared DNA sequence data for two laboratory A mexicanum and one A tigrinum to identify 702 million high confidence polymorphisms distributed across the 32 Gb genome. While the wild-caught A tigrinum was generally more polymorphic in a genome-wide sense, several multi-megabase regions were identified from A mexicanum genomes that were actually more polymorphic than A tigrinum. Analysis of polymorphism and repeat content reveals that these regions likely originated from the intentional hybridization of A mexicanum and A tigrinum that was used to introduce the albino mutation into laboratory stocks., Conclusions: Our findings show that axolotl genomes are variable with respect to introgressed DNA from a highly polymorphic species. It seems likely that other divergent regions will be discovered with additional sequencing of A mexicanum. This has practical implications for designing molecular probes and suggests a need to study A mexicanum phenotypic variation and genome evolution across the tiger salamander clade., (© 2020 Wiley Periodicals LLC.)

Published

2021

32. Geography is more important than life history in the recent diversification of the tiger salamander complex.

Author

Everson KM, Gray LN, Jones AG, Lawrence NM, Foley ME, Sovacool KL, Kratovil JD, Hotaling S, Hime PM, Storfer A, Parra-Olea G, Percino-Daniel R, Aguilar-Miguel X, O'Neill EM, Zambrano L, Shaffer HB, and Weisrock DW

Subjects

Ambystoma mexicanum genetics, Animals, Databases, Genetic, Gene Flow, Genetics, Population methods, Geography, Larva genetics, Metamorphosis, Biological genetics, North America, Phylogeny, Ambystoma genetics, Ambystoma metabolism

Abstract

The North American tiger salamander species complex, including its best-known species, the Mexican axolotl, has long been a source of biological fascination. The complex exhibits a wide range of variation in developmental life history strategies, including populations and individuals that undergo metamorphosis; those able to forego metamorphosis and retain a larval, aquatic lifestyle (i.e., paedomorphosis); and those that do both. The evolution of a paedomorphic life history state is thought to lead to increased population genetic differentiation and ultimately reproductive isolation and speciation, but the degree to which it has shaped population- and species-level divergence is poorly understood. Using a large multilocus dataset from hundreds of samples across North America, we identified genetic clusters across the geographic range of the tiger salamander complex. These clusters often contain a mixture of paedomorphic and metamorphic taxa, indicating that geographic isolation has played a larger role in lineage divergence than paedomorphosis in this system. This conclusion is bolstered by geography-informed analyses indicating no effect of life history strategy on population genetic differentiation and by model-based population genetic analyses demonstrating gene flow between adjacent metamorphic and paedomorphic populations. This fine-scale genetic perspective on life history variation establishes a framework for understanding how plasticity, local adaptation, and gene flow contribute to lineage divergence. Many members of the tiger salamander complex are endangered, and the Mexican axolotl is an important model system in regenerative and biomedical research. Our results chart a course for more informed use of these taxa in experimental, ecological, and conservation research., Competing Interests: The authors declare no competing interest.

Published

2021

33. Characterization of axolotl lampbrush chromosomes by fluorescence in situ hybridization and immunostaining.

Author

Keinath MC, Davidian A, Timoshevskiy V, Timoshevskaya N, and Gall JG

Subjects

Ambystoma mexicanum immunology, Animals, Centromere genetics, Chromosome Mapping, Chromosomes immunology, Chromosomes, Artificial, Bacterial genetics, Chromosomes, Artificial, Bacterial immunology, Oocytes growth & development, Oocytes ultrastructure, Ambystoma mexicanum genetics, Centromere ultrastructure, Chromosomes genetics, In Situ Hybridization, Fluorescence, Transcription, Genetic

Abstract

The lampbrush chromosomes (LBCs) in oocytes of the Mexican axolotl (Ambystoma mexicanum) were identified some time ago by their relative lengths and predicted centromeres, but they have never been associated completely with the mitotic karyotype, linkage maps or genome assembly. We identified 9 of the axolotl LBCs using RNAseq to identify actively transcribed genes and 13 BAC (bacterial artificial clone) probes containing pieces of active genes. Using read coverage analysis to find candidate centromere sequences, we developed a centromere probe that localizes to all 14 centromeres. Measurements of relative LBC arm lengths and polymerase III localization patterns enabled us to identify all LBCs. This study presents a relatively simple and reliable way to identify each axolotl LBC cytologically and to anchor chromosome-length sequences (from the axolotl genome assembly) to the physical LBCs by immunostaining and fluorescence in situ hybridization. Our data will facilitate a more detailed transcription analysis of individual LBC loops., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

34. The giant axolotl genome uncovers the evolution, scaling, and transcriptional control of complex gene loci.

Author

Schloissnig S, Kawaguchi A, Nowoshilow S, Falcon F, Otsuki L, Tardivo P, Timoshevskaya N, Keinath MC, Smith JJ, Voss SR, and Tanaka EM

Subjects

Animals, Chromosomes genetics, Genetic Loci, Transcriptome, Ambystoma mexicanum genetics, Evolution, Molecular, Genome

Abstract

Vertebrates harbor recognizably orthologous gene complements but vary 100-fold in genome size. How chromosomal organization scales with genome expansion is unclear, and how acute changes in gene regulation, as during axolotl limb regeneration, occur in the context of a vast genome has remained a riddle. Here, we describe the chromosome-scale assembly of the giant, 32 Gb axolotl genome. Hi-C contact data revealed the scaling properties of interphase and mitotic chromosome organization. Analysis of the assembly yielded understanding of the evolution of large, syntenic multigene clusters, including the Major Histocompatibility Complex (MHC) and the functional regulatory landscape of the Fibroblast Growth Factor 8 ( Axfgf8 ) region. The axolotl serves as a primary model for studying successful regeneration., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021

35. Single-cell RNA-seq reveals novel mitochondria-related musculoskeletal cell populations during adult axolotl limb regeneration process.

Author

Qin T, Fan CM, Wang TZ, Sun H, Zhao YY, Yan RJ, Yang L, Shen WL, Lin JX, Bunpetch V, Cucchiarini M, Clement ND, Mason CE, Nakamura N, Bhonde R, Yin Z, and Chen X

Subjects

Amputation, Surgical, Animals, Cell Differentiation, Extremities physiology, Extremities surgery, Gene Expression Profiling, RNA-Seq, Single-Cell Analysis, Transcriptome, Ambystoma mexicanum genetics, Ambystoma mexicanum physiology, Mitochondria genetics, Muscle, Skeletal physiology, Regeneration genetics

Abstract

While the capacity to regenerate tissues or limbs is limited in mammals, including humans, axolotls are able to regrow entire limbs and major organs after incurring a wound. The wound blastema has been extensively studied in limb regeneration. However, due to the inadequate characterization of ECM and cell subpopulations involved in the regeneration process, the discovery of the key drivers for human limb regeneration remains unknown. In this study, we applied large-scale single-cell RNA sequencing to classify cells throughout the adult axolotl limb regeneration process, uncovering a novel regeneration-specific mitochondria-related cluster supporting regeneration through energy providing and the ECM secretion (COL2+) cluster contributing to regeneration through cell-cell interactions signals. We also discovered the dedifferentiation and re-differentiation of the COL1+/COL2+ cellular subpopulation and exposed a COL2-mitochondria subcluster supporting the musculoskeletal system regeneration. On the basis of these findings, we reconstructed the dynamic single-cell transcriptome of adult axolotl limb regenerative process, and identified the novel regenerative mitochondria-related musculoskeletal populations, which yielded deeper insights into the crucial interactions between cell clusters within the regenerative microenvironment.

Published

2021

36. The first report on circulating microRNAs at Pre- and Post-metamorphic stages of axolotls.

Author

Demircan T, Sibai M, Avşaroğlu ME, Altuntaş E, and Ovezmyradov G

Subjects

Animals, Gene Expression Regulation, Developmental genetics, MicroRNAs genetics, Regeneration genetics, Saliva chemistry, Sequence Analysis, RNA, Ambystoma mexicanum embryology, Ambystoma mexicanum genetics, Circulating MicroRNA genetics, Metamorphosis, Biological genetics, MicroRNAs blood

Abstract

MicroRNAs (miRNAs) are endogenously coded small RNAs, implicated in post-transcriptional gene regulation by targeting messenger RNAs (mRNAs). Circulating miRNAs are cell-free molecules, found in body fluids, such as blood and saliva, and emerged recently as potential diagnostic biomarkers. Functions of circulating miRNAs and their roles in target tissues have been extensively investigated in mammals, and the reports on circulating miRNAs in non-mammalian clades are largely missing. Salamanders display remarkable regenerative potential, and the Mexican axolotl (Ambystoma mexicanum), a critically endangered aquatic salamander, has emerged as a powerful model organism in regeneration and developmental studies. This study aimed to explore the circulating miRNA signature in axolotl blood plasma. Small RNA sequencing on plasma samples revealed 16 differentially expressed (DE) circulating miRNAs between neotenic and metamorphic stages out of identified 164 conserved miRNAs. Bioinformatics predictions provided functional annotation of detected miRNAs for both stages and enrichment of DE miRNAs in cancer-related and developmental pathways was notable. Comparison with previous reports on axolotl miRNAs unraveled common and unique members of the axolotl circulating miRNome. Overall, this work provides novel insights into non-mammalian aspects of circulating miRNA biology and expands the multi-omics toolkit for this versatile model organism., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2021

37. Exploring the role of microRNAs in axolotl regeneration.

Author

Abo-Al-Ela HG and Burgos-Aceves MA

Subjects

Ambystoma mexicanum growth & development, Animals, Gene Expression genetics, Gene Expression Regulation, Developmental genetics, Humans, Ambystoma mexicanum genetics, MicroRNAs genetics, Regeneration genetics

Abstract

The axolotl, Ambystoma mexicanum, is used extensively for research in developmental biology, particularly for its ability to regenerate and restore lost organs, including in the nervous system, to full functionality. Regeneration in mammals typically depends on the healing process and scar formation with limited replacement of lost tissue. Other organisms, such as spiny mice (Acomys cahirinus), salamanders, and zebrafish, are able to regenerate some damaged body components. Blastema is a tissue that is formed after tissue injury in such organisms and is composed of progenitor cells or dedifferentiated cells that differentiate into various cell types during regeneration. Thus, identifying the molecules responsible for initiation of blastema formation is an important aspect for understanding regeneration. Introns, a major source of noncoding RNAs (ncRNAs), have characteristic sizes in the axolotl, particularly in genes associated with development. These ncRNAs, particularly microRNAs (miRNAs), exhibit dynamic regulation during regeneration. These miRNAs play an essential role in timing and control of gene expression to order and organize processes necessary for blastema creation. Master keys or molecules that underlie the remarkable regenerative abilities of the axolotl remain to be fully explored and exploited. Further and ongoing research on regeneration promises new knowledge that may allow improved repair and renewal of human tissues., (© 2020 Wiley Periodicals LLC.)

Published

2021

38. Limb regeneration in salamanders: the plethodontid tale.

Author

Arenas-Gómez CM and Delgado JP

Subjects

Animals, Wound Healing, Ambystoma mexicanum genetics, Ambystoma mexicanum growth & development, Extremities growth & development, Regeneration, Urodela genetics, Urodela growth & development

Abstract

Salamanders are the only vertebrates that can regenerate limbs as adults. This makes them ideal models to investigate the cellular and molecular mechanisms of tissue regeneration. Ambystoma mexicanum and Nothopthalmus viridescens have long served as primary salamander models of limb regeneration, and the recent sequencing of the axolotl genome now provides a blueprint to mine regeneration insights from other salamander species. In particular, there is a need to study South American plethodontid salamanders that present different patterns of limb development and regeneration. A broader sampling of species using next-generation sequencing approaches is needed to reveal shared and unique mechanisms of regeneration, and more generally, the evolutionary history of salamander limb regeneration.

Published

2021

39. Dynamic cell transition and immune response landscapes of axolotl limb regeneration revealed by single-cell analysis.

Author

Li H, Wei X, Zhou L, Zhang W, Wang C, Guo Y, Li D, Chen J, Liu T, Zhang Y, Ma S, Wang C, Tan F, Xu J, Liu Y, Yuan Y, Chen L, Wang Q, Qu J, Shen Y, Liu S, Fan G, Liu L, Liu X, Hou Y, Liu GH, Gu Y, and Xu X

Subjects

Ambystoma mexicanum immunology, Amputation, Surgical, Animals, Biomarkers metabolism, Blastomeres cytology, Blastomeres immunology, Cell Lineage immunology, Connective Tissue Cells cytology, Connective Tissue Cells immunology, Epithelial Cells cytology, Epithelial Cells immunology, Forelimb, Gene Expression, High-Throughput Nucleotide Sequencing, Humans, Immunity, Peroxiredoxins immunology, Regeneration immunology, Regenerative Medicine methods, Ambystoma mexicanum genetics, Cell Lineage genetics, Peroxiredoxins genetics, Regeneration genetics, Single-Cell Analysis methods

Published

2021

40. Genomics and epigenomics of axolotl regeneration.

Author

Sámano C, González-Barrios R, Castro-Azpíroz M, Torres-García D, Ocampo-Cervantes JA, Otero-Negrete J, and Soto-Reyes E

Subjects

Animals, Extremities, Gene Expression Profiling, Genome, Genomics, Ambystoma mexicanum genetics, Ambystoma mexicanum growth & development, Epigenomics, Regeneration genetics

Abstract

The axolotl ( Ambystoma mexicanum) has been a widely studied organism due to its capacity to regenerate most of its cells, tissues and whole-body parts. Since its genome was sequenced, several molecular tools have been developed to study the mechanisms behind this outstanding and extraordinary ability. The complexity of its genome due to its sheer size and the disproportionate expansion of a large number of repetitive elements, may be a key factor at play during tissue remodeling and regeneration mechanisms. Transcriptomic analysis has provided information to identify candidate genes networks and pathways that might define successful or failed tissue regeneration. Nevertheless, the epigenetic machinery that may participate in this phenomenon has largely not been studied. In this review, we outline a broad overview of both genetic and epigenetic molecular processes related to regeneration in axolotl, from the macroscopic to the molecular level. We also explore the epigenetic mechanisms behind regenerative pathways, and its potential importance in future regeneration research. Altogether, understanding the genomics and global regulation in axolotl will be key for elucidating the special biology of this organism and the fantastic phenomenon that is regeneration.

Published

2021

41. Variation under domestication in animal models: the case of the Mexican axolotl.

Author

Torres-Sánchez M

Subjects

Animals, Genetic Variation, Genome, Mexico, Phenotype, Ambystoma mexicanum genetics, Domestication

Abstract

Background: Species adaptation to laboratory conditions is a special case of domestication that has modified model organisms phenotypically and genetically. The characterisation of these changes is crucial to understand how this variation can affect the outcome of biological experiments. Yet despite the wide use of laboratory animals in biological research, knowledge of the genetic diversity within and between different strains and populations of some animal models is still scarce. This is particularly the case of the Mexican axolotl, which has been bred in captivity since 1864., Results: Using gene expression data from nine different projects, nucleotide sequence variants were characterised, and distinctive genetic background of the experimental specimens was uncovered. This study provides a catalogue of thousands of nucleotide variants along predicted protein-coding genes, while identifying genome-wide differences between pigment phenotypes in laboratory populations., Conclusions: Awareness of the genetic variation could guide a better experimental design while helping to develop molecular tools for monitoring genetic diversity and studying gene functions in laboratory axolotls. Overall, this study highlights the cross-taxa utility that transcriptomic data might have to assess the genetic variation of the experimental specimens, which might help to shorten the journey towards reproducible research.

Published

2020

42. Identification of immune and non-immune cells in regenerating axolotl limbs by single-cell sequencing.

Author

Rodgers AK, Smith JJ, and Voss SR

Subjects

Ambystoma mexicanum blood, Ambystoma mexicanum genetics, Animals, Biomarkers metabolism, Female, Quality Control, RNA, Messenger genetics, RNA, Messenger metabolism, Ambystoma mexicanum immunology, Extremities physiology, Regeneration physiology, Sequence Analysis, DNA, Single-Cell Analysis

Abstract

Immune cells are known to be critical for successful limb regeneration in the axolotl (Ambystoma mexicanum), but many details regarding their identity, behavior, and function are yet to be resolved. We isolated peripheral leukocytes from the blood of adult axolotls and then created two samples for single-cell sequencing: 1) peripheral leukocytes (N = 7889) and 2) peripheral leukocytes with presumptive macrophages from the intraperitoneal cavity (N = 4998). Using k-means clustering, we identified 6 cell populations from each sample that presented gene expression patterns indicative of erythrocyte, thrombocyte, neutrophil, B-cell, T-cell, and myeloid cell populations. A seventh, presumptive macrophage cell population was identified uniquely from sample 2. We then isolated cells from amputated axolotl limbs at 1 and 6 days post-amputation (DPA) and performed single cell sequencing (N = 8272 and 9906 cells respectively) to identify immune and non-immune cell populations. Using k-means clustering, we identified 8 cell populations overall, with the majority of cells expressing erythrocyte-specific genes. Even though erythrocytes predominated, we used an unbiased approach to identify infiltrating neutrophil, macrophage, and lymphocyte populations at both time points. Additionally, populations expressing genes for epidermal cells, fibroblast-like cells, and endothelial cells were also identified. Consistent with results from previous experimental studies, neutrophils were more abundant at 1 DPA than 6 DPA, while macrophages and non-immune cells exhibited inverse abundance patterns. Of note, we identified a small population of fibroblast-like cells at 1 DPA that was represented by considerably more cells at 6 DPA. We hypothesize that these are early progenitor cells that give rise to the blastema. The enriched gene sets from our work will aid future single-cell investigations of immune cell diversity and function during axolotl limb regeneration., (Copyright © 2020 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2020

43. Introducing www.axolotl-omics.org - an integrated -omics data portal for the axolotl research community.

Author

Nowoshilow S and Tanaka EM

Subjects

Animals, Gene Editing, Genomics, Humans, Ambystoma mexicanum genetics, Computational Biology methods, Regeneration genetics, Transcriptome genetics

Abstract

Genomic resources are indispensable for biological investigations in model organisms. In recent years, a number of genomic resources including a full genome assembly, extensive transcriptomic data, as well as genome editing has been developed for the axolotl, a classical model organism for developmental, neurobiological and regeneration studies, making the axolotl a highly versatile system. Here we describe the Axolotl-omics website that allows rapid ortholog searches, and access to genome and transcriptomic resources., (Copyright © 2020 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2020

44. Neural regulation in tooth regeneration of Ambystoma mexicanum.

Author

Makanae A, Tajika Y, Nishimura K, Saito N, Tanaka JI, and Satoh A

Subjects

Ambystoma mexicanum genetics, Animals, Animals, Genetically Modified, Bone Morphogenetic Protein 2 genetics, Bone Morphogenetic Protein 7 genetics, Fibroblast Growth Factor 2 genetics, Fibroblast Growth Factor 8 genetics, Green Fluorescent Proteins genetics, Hedgehog Proteins genetics, Imaging, Three-Dimensional, Mandible innervation, Mandible surgery, Odontoblasts cytology, Tooth anatomy & histology, Ambystoma mexicanum physiology, Regeneration physiology, Tooth physiology

Abstract

The presence of nerves is an important factor in successful organ regeneration in amphibians. The Mexican salamander, Ambystoma mexicanum, is able to regenerate limbs, tail, and gills when nerves are present. However, the nerve-dependency of tooth regeneration has not been evaluated. Here, we reevaluated tooth regeneration processes in axolotls using a three-dimensional reconstitution method called CoMBI and found that tooth regeneration is nerve-dependent although the dentary bone is independent of nerve presence. The induction and invagination of the dental lamina were delayed by denervation. Exogenous Fgf2, Fgf8, and Bmp7 expression could induce tooth placodes even in the denervated mandible. Our results suggest that the role of nerves is conserved and that Fgf+Bmp signals play key roles in axolotl organ-level regeneration. The presence of nerves is an important factor in successful organ regeneration in amphibians. The Mexican salamander, Ambystoma mexicanum, is able to regenerate limbs, tail, and gills when nerves are present. However, the nervedependency of tooth regeneration has not been evaluated. Here, we reevaluated tooth regeneration processes in axolotls using a three-dimensional reconstitution method called CoMBI and found that tooth regeneration is nerve-dependent although the dentary bone is independent of nerve presence. The induction and invagination of the dental lamina were delayed by denervation. Exogenous Fgf2, Fgf8, and Bmp7 expression could induce tooth placodes even in the denervated mandible. Our results suggest that the role of nerves is conserved and that Fgf+Bmp signals play key roles in axolotl organ-level regeneration.

Published

2020

45. Small circRNAs with self-cleaving ribozymes are highly expressed in diverse metazoan transcriptomes.

Author

Cervera A and de la Peña M

Subjects

Ambystoma mexicanum genetics, Animals, Anthozoa genetics, Bivalvia genetics, Genome, RNA, Catalytic chemistry, RNA, Circular biosynthesis, Retroelements, Tandem Repeat Sequences, Transcriptome, RNA, Catalytic genetics, RNA, Catalytic metabolism, RNA, Circular metabolism

Abstract

Ribozymes are catalytic RNAs present in modern genomes but regarded as remnants of a prebiotic RNA world. The paradigmatic hammerhead ribozyme (HHR) is a small self-cleaving motif widespread from bacterial to human genomes. Here, we report that most of the classical type I HHRs frequently found in the genomes of animals are contained within a novel family of non-autonomous non-LTR retrotransposons of the retrozyme class. These retroelements are expressed as abundant linear and circular RNAs of ∼170-400 nt in different animal tissues. Bioinformatic and in vitro analyses indicate an efficient self-cleavage of the HHRs harboured in most invertebrate retrozymes, whereas HHRs in retrozymes of vertebrates, such as the axolotl and other amphibians, require to act as dimeric motifs to reach higher self-cleavage rates. Ligation assays of retrozyme RNAs with a protein ligase versus HHR self-ligation indicate that, most likely, tRNA ligases and not the ribozymes are involved in the step of RNA circularization. Altogether, these results confirm the existence of a new and conserved pathway in animals and, likely, eukaryotes in general, for the efficient biosynthesis of RNA circles through small ribozymes, which opens the door for the development of new tools in the emerging field of study of circRNAs., (© The Author(s) 2020. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2020

46. Transcriptome analysis of axolotl oropharyngeal explants during taste bud differentiation stages.

Author

Kohli P, Marazzi L, and Eastman D

Subjects

Animals, Endoderm physiology, Gene Expression Profiling methods, Regeneration genetics, Regeneration physiology, Ambystoma mexicanum genetics, Ambystoma mexicanum physiology, Cell Differentiation physiology, Oropharynx physiology, Taste Buds physiology, Transcriptome genetics

Abstract

The Mexican salamander, Ambystoma mexicanum (Axolotl), is an excellent vertebrate model system to understand development and regeneration. Studies in axolotl embryos have provided important insights into taste bud development. Taste bud specification and determination occur in the oropharyngeal endoderm of axolotl embryos during gastrulation and neurulation, respectively, whereas taste bud innervation and taste cell differentiation occur later in development. Axolotl embryos are amenable to microsurgery, and tissue explants develop readily in vitro. We performed RNA-seq analysis to investigate the differential expression of genes in oropharyngeal explants at several stages of taste cell differentiation. Since the axolotl genome has only recently been sequenced, we used a Trinity pipeline to perform de novo assembly of sequencing reads. Linear models for RNA-seq data were used to identify differentially expressed genes. We found 1234 unique genes differentially expressed during taste cell differentiation stages. We validated four of these genes using RTqPCR and performed GO functional analysis. The differential expression of these genes suggests that they may play a role in taste cell differentiation in axolotls., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2020

47. Comparison of protein expression profile of limb regeneration between neotenic and metamorphic axolotl.

Author

Sibai M, Altuntaş E, Süzek BE, Şahin B, Parlayan C, Öztürk G, Baykal AT, and Demircan T

Subjects

Ambystoma mexicanum genetics, Ambystoma mexicanum immunology, Animals, Gene Expression Regulation, Gene Ontology, Immunity, Ambystoma mexicanum growth & development, Ambystoma mexicanum metabolism, Extremities physiology, Metamorphosis, Biological, Proteome metabolism, Regeneration physiology

Abstract

The axolotl (Ambystoma mexicanum) salamander, a urodele amphibian, has an exceptional regenerative capacity to fully restore an amputated limb throughout the life-long lasting neoteny. By contrast, when axolotls are experimentally induced to metamorphosis, attenuation of the limb's regenerative competence is noticeable. Here, we sought to discern the proteomic profiles of the early stages of blastema formation of neotenic and metamorphic axolotls after limb amputation by employing LC-MS/MS technology. We quantified a total of 714 proteins and qRT-PCR for selected genes was performed to validate the proteomics results and provide evidence for the putative link between immune system activity and regenerative potential. This study provides new insights for examination of common and distinct molecular mechanisms in regeneration-permissive neotenic and regeneration-deficient metamorphic stages at the proteome level., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2020

48. Generation of Chimeric Axolotls with Mutant Haploid Limbs Through Embryonic Grafting.

Author

Sanor LD, Flowers GP, and Crews CM

Subjects

Animals, Diploidy, Embryo, Nonmammalian metabolism, Female, Fluorescence, Green Fluorescent Proteins metabolism, Male, Mutagenesis genetics, Phenotype, Regeneration genetics, Ambystoma mexicanum embryology, Ambystoma mexicanum genetics, Chimera genetics, Extremities embryology, Haploidy, Mutation genetics

Abstract

A growing set of genetic techniques and resources enable researchers to probe the molecular origins of the ability of some species of salamanders, such as axolotls, to regenerate entire limbs as adults. Here, we outline techniques used to generate chimeric axolotls with Cas9-mutagenized haploid forelimbs that can be used for exploring gene function and the fidelity of limb regeneration. We combine several embryological and genetic techniques, including haploid generation via in vitro activation, CRISPR/Cas9 mutagenesis, and tissue grafting into one protocol to produce a unique system for haploid genetic screening in a model organism of regeneration. This strategy reduces the number of animals, space, and time required for the functional analysis of genes in limb regeneration. This also permits the investigation of regeneration-specific functions of genes that may be required for other essential processes, such as organogenesis, tissue morphogenesis, and other essential embryonic processes. The method described here is a unique platform for conducting haploid genetic screening in a vertebrate model system.

Published

2020

49. Multiplex CRISPR/Cas screen in regenerating haploid limbs of chimeric Axolotls.

Author

Sanor LD, Flowers GP, and Crews CM

Subjects

Alleles, Ambystoma mexicanum embryology, Animals, Catalase genetics, Fetuin-B genetics, Gene Editing, Gene Expression Regulation, Developmental, Genetic Testing methods, Karyotype, Methyltransferases genetics, Monophenol Monooxygenase genetics, Mutation, Regeneration, Sequence Analysis, Ambystoma mexicanum genetics, Ambystoma mexicanum physiology, CRISPR-Cas Systems, Haploidy

Abstract

Axolotls and other salamanders can regenerate entire limbs after amputation as adults, and much recent effort has sought to identify the molecular programs controlling this process. While targeted mutagenesis approaches like CRISPR/Cas9 now permit gene-level investigation of these mechanisms, genetic screening in the axolotl requires an extensive commitment of time and space. Previously, we quantified CRISPR/Cas9-generated mutations in the limbs of mosaic mutant axolotls before and after regeneration and found that the regenerated limb is a highfidelity replicate of the original limb (Flowers et al. 2017). Here, we circumvent aforementioned genetic screening limitations and present methods for a multiplex CRISPR/Cas9 haploid screen in chimeric axolotls (MuCHaChA), which is a novel platform for haploid genetic screening in animals to identify genes essential for limb regeneration., Competing Interests: LS, GF, CC No competing interests declared, (© 2020, Sanor et al.)

Published

2020

50. Lissamphibian limbs and the origins of tetrapod hox domains.

Author

Woltering JM, Holzem M, and Meyer A

Subjects

Ambystoma mexicanum genetics, Animals, Biological Evolution, Cichlids genetics, Extremities embryology, Extremities pathology, Genes, Homeobox physiology, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, In Situ Hybridization, Organogenesis, Transcription Factors metabolism, Xenopus Proteins genetics, Xenopus Proteins metabolism, Xenopus laevis genetics, Animal Fins metabolism, Gene Expression Regulation, Developmental genetics, Genes, Homeobox genetics

Abstract

The expression and function of hox genes have played a key role in the debate on the evolution of limbs from fins. As an early branching tetrapod lineage, lissamphibians may provide information on the origin of the limb's hox domains and particularly how the plesiomorphic tetrapod pattern compares to the hox pattern present in fish fins. Here, we comparatively investigated the expression of hox genes in the developing limbs of axolotl and Xenopus laevis as well as in the fins of the direct developing cichlid Astatotilapia burtoni. In contrast to axolotl, which has only very low digital expression of hoxd11, Xenopus limbs recapitulate the reverse collinear hoxd expression pattern known from amniotes with clearly defined proximal and distal hoxd11 expression domains. For hoxa genes, we observe that in Xenopus limbs, as in axolotl, a clear distal domain of hoxa11 expression is present, although in the presence of a hoxa11 antisense transcript. Investigation of fins reveals the presence of hoxa11 antisense transcription in the developing fin rays in a domain similar to that of hoxa13 and overlapping with hoxa11 sense transcription. Our results indicate that full exclusion of hoxa11 from the autopod only became firmly established in amniotes. The distal antisense transcription of hoxa11, however, appears to predate the evolution of the limb, but likely originated without the concurrent implementation of the transcriptional suppression mechanism that causes mutually exclusive hoxa11 and hoxa13 domains in amniotes., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019