Developmental transitions include molting in some invertebrates and the metamorphosis of insects and amphibians. While the study of Caenorhabditis elegans larval transitions was crucial to determine ...the genetic control of these transitions, Drosophila melanogaster and Xenopus laevis have been classic models to study the role of hormones in metamorphosis. Here we review how heterochronic genes (lin-4, let-7, lin-28, lin-41), hormones (dafachronic acid, ecdysone, thyroid hormone) and the environment regulate developmental transitions. Recent evidence suggests that some heterochronic genes also regulate transitions in higher organisms that they are controlled by hormones involved in metamorphosis. We also discuss evidence demonstrating that heterochronic genes and hormones regulate the proliferation and differentiation of embryonic and neural stem cells. We propose the hypothesis that developmental transitions are regulated by an evolutionary conserved mechanism in which heterochronic genes and hormones interact to control stem/progenitor cells proliferation, cell cycle exit, quiescence and differentiation and determine the proper timing of developmental transitions. Finally, we discuss the relevance of these studies to understand post-embryonic development, puberty and regeneration in humans.
•Larval transitions in nematodes are regulated by heterochronic genes.•Hormones regulate metamorphosis in insects and amphibians.•Regulation of stem and progenitor cells is crucial for developmental transitions.•Evidence suggesting that heterochronic genes and hormones are linked is discussed.
Full text
Available for:
GEOZS, IJS, IMTLJ, KILJ, KISLJ, NLZOH, NUK, OILJ, PNG, SAZU, SBCE, SBJE, UILJ, UL, UM, UPCLJ, UPUK, ZAGLJ, ZRSKP
The capacity to regenerate the spinal cord after an injury is a coveted trait that only a limited group of nonmammalian organisms can achieve. In Xenopus laevis, this capacity is only present during ...larval or tadpole stages, but is absent during postmetamorphic frog stages. This provides an excellent model for comparative studies between a regenerative and a nonregenerative stage to identify the cellular and molecular mechanisms that explain this difference in regenerative potential. Here, we used iTRAQ chemistry to obtain a quantitative proteome of the spinal cord 1 day after a transection injury in regenerative and nonregenerative stage animals, and used sham operated animals as controls. We quantified a total of 6,384 proteins, with 172 showing significant differential expression in the regenerative stage and 240 in the nonregenerative stage, with an overlap of only 14 proteins. Functional enrichment analysis revealed that although the regenerative stage downregulated synapse/vesicle and mitochondrial proteins, the nonregenerative stage upregulated lipid metabolism proteins, and downregulated ribosomal and translation control proteins. Furthermore, STRING network analysis showed that proteins belonging to these groups are highly interconnected, providing interesting candidates for future functional studies. Data are available via ProteomeXchange with identifier PXD006993.
Full text
Available for:
GEOZS, IJS, IMTLJ, KILJ, KISLJ, NLZOH, NUK, OILJ, PNG, SAZU, SBCE, SBJE, UILJ, UL, UM, UPCLJ, UPUK, ZAGLJ, ZRSKP
Many people around the world suffer from some form of paralysis caused by spinal cord injury (SCI), which has an impact on quality and life expectancy. The spinal cord is part of the central nervous ...system (CNS), which in mammals is unable to regenerate, and to date, there is a lack of full functional recovery therapies for SCI. These injuries start with a rapid and mechanical insult, followed by a secondary phase leading progressively to greater damage. This secondary phase can be potentially modifiable through targeted therapies. The growing literature, derived from mammalian and regenerative model studies, supports a leading role for mitochondria in every cellular response after SCI: mitochondrial dysfunction is the common event of different triggers leading to cell death, cellular metabolism regulates the immune response, mitochondrial number and localization correlate with axon regenerative capacity, while mitochondrial abundance and substrate utilization regulate neural stem progenitor cells self-renewal and differentiation. Herein, we present a comprehensive review of the cellular responses during the secondary phase of SCI, the mitochondrial contribution to each of them, as well as evidence of mitochondrial involvement in spinal cord regeneration, suggesting that a more in-depth study of mitochondrial function and regulation is needed to identify potential targets for SCI therapeutic intervention.
Full text
Available for:
EMUNI, FZAB, GEOZS, IJS, IMTLJ, KILJ, KISLJ, MFDPS, NUK, OILJ, PNG, SAZU, SBCE, SBMB, SBNM, UKNU, UL, UM, UPUK, VKSCE, ZAGLJ
•Xenopus brain and spinal cord regenerate in the larva, but not after metamorphosis.•Optic nerve regeneration is maintained throughout frog lifespan.•During metamorphosis, remodeling of brain stem ...supraspinal tracts takes place.•Sox2+ progenitor cells in the brain and spinal cord respond to injury.•Studying Xenopus can provide important insights into improving neural regeneration.
While an injury to the central nervous system (CNS) in humans and mammals is irreversible, amphibians and teleost fish have the capacity to fully regenerate after severe injury to the CNS. Xenopus laevis has a high potential to regenerate the brain and spinal cord during larval stages (47–54), and loses this capacity during metamorphosis. The optic nerve has the capacity to regenerate throughout the frog’s lifespan. Here, we review CNS regeneration in frogs, with a focus in X. laevis, but also provide some information about X. tropicalis and other frogs. We start with an overview of the anatomy of the Xenopus CNS, including the main supraspinal tracts that emerge from the brain stem, which play a key role in motor control and are highly conserved across vertebrates. We follow with the advantages of using Xenopus, a classical laboratory model organism, with increasing availability of genetic tools like transgenesis and genome editing, and genomic sequences for both X. laevis and X. tropicalis. Most importantly, Xenopus provides the possibility to perform intra-species comparative experiments between regenerative and non-regenerative stages that allow the identification of which factors are permissive for neural regeneration, and/or which are inhibitory. We aim to provide sufficient evidence supporting how useful Xenopus can be to obtain insights into our understanding of CNS regeneration, which, complemented with studies in mammalian vertebrate model systems, can provide a collaborative road towards finding novel therapeutic approaches for injuries to the CNS.
Full text
Available for:
GEOZS, IJS, IMTLJ, KILJ, KISLJ, NUK, OILJ, PNG, SAZU, SBCE, SBJE, UL, UM, UPCLJ, UPUK, ZRSKP
The bryophytes of Capitán Prat province have remained one of the least explored in Chile. The eventual construction of several dams on the rivers Baker and Pascua required prospection of all groups ...of organisms including bryophytes, work that was facilitated by the recent construction of vehicular roads that now offer easy access to previously almost unaccessible locations. The results of intense bryophyte collecting during the austral summer of 2007 are here presented. A total of 260 moss taxa are reported for the province, corresponding to 256 species and four infraspecific taxa, of which 211 are new records for the province, 54 are new for Aisén Region, and two are new records for continental Chile (
(Hedw.) Lindb. and Rigodium toxarion var. robustum (Broth.) Zomlefer). Twelve species extend their known distribution ranges to the north, whereas 49 extend them to the south.
Full text
Available for:
IZUM, KILJ, NUK, PILJ, PNG, SAZU, UL, UM, UPUK
Background
The thyroid hormones—thyroxine (T4) and 3,5,3′triiodothyronine (T3)—regulate the development of the central nervous system (CNS) in vertebrates by acting in different cell types. Although ...several T3 target genes have been identified in the brain, the changes in the transcriptome in response to T3 specifically in neural stem and progenitor cells (NSPCs) during the early steps of NSPCs activation and neurogenesis have not been studied in vivo. Here, we characterized the transcriptome of FACS‐sorted NSPCs in response to T3 during Xenopus laevis metamorphosis.
Results
We identified 1252 upregulated and 726 downregulated genes after 16 hours of T3 exposure. Gene ontology and Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis revealed that T3‐upregulated genes were significantly enriched in rRNA processing and maturation, protein folding, ribosome biogenesis, translation, mitochondrial function, and proteasome. These results suggest that NSPCs activation induced by T3 is characterized by an early proteome remodeling through the synthesis of the translation machinery and the degradation of proteins by the proteasome.
Conclusion
This work provides new insights into the dynamics of activation of NPSCs in vivo in response to T3 during a critical period of neurogenesis in the metamorphosis.
Key Findings
We characterized the transcriptome of Xenopus neural stem and progenitor cells (NSPCs) in response to 16 hours of T3 exposure.
T3‐upregulated genes were significantly enriched in ribosome biogenesis, proteasome and mitochondrial function.
Our results reveal new insights into the early dynamics of NSPCs activation during neurogenesis.
Full text
Available for:
FZAB, GIS, IJS, KILJ, NLZOH, NUK, OILJ, SAZU, SBCE, SBMB, UL, UM, UPUK
Spinal cord injury (SCI) is a permanent affliction, which affects the central nervous system (CNS) motor and sensory nerves, resulting in paralysis beneath the injury site. To date, there is no ...functional recovery therapy for SCI, and there is a lack of clarity regarding the many complexes and dynamic events occurring after SCI. Many non-mammalian organisms can regenerate after severe SCI, such as teleost fishes, urodele amphibians, and larval stages of anuran amphibians, including Xenopus laevis tadpoles. These are bona fide model organisms to study and understand the response to SCI and the mechanisms underlying successful regenerative processes. This type of research can lead to the identification of potential targets for SCI therapeutic intervention. This article describes how to perform Xenopus laevis tadpole spinal cord transection, including husbandry, surgery, postsurgery care, and functional test evaluation. This injury method can be applied for elucidating the different steps of spinal cord regeneration by studying the cellular, molecular, and genetic mechanisms, as well as histological and functional evolution after SCI and during spinal cord regeneration.
El conocimiento detallado de la biodiversidad constituye un insumo imprescindible para un diseño adecuado de estrategias de conservación. En cuanto a la diversidad de briófitos, Chile aún carece de ...información florística en grandes extensiones del país. Como contribución al conocimiento de la historia natural de la zona central, presentamos un catálogo de los briófitos del Parque Nacional La Campana, ubicado en la Región de Valparaíso. Se reportan 148 taxones de briófitos, correspondientes a 111 especies de musgos, 33 hepáticas y cuatro antocerotes. Entre éstos se encuentran nuevos registros regionales y provinciales, además de extensiones de límites de distribución. Se reporta Bryum klinggraeffii por primera vez para Chile. Se discute la composición biogeográfica de la flora local y se comentan las particularidades ecológicas de la flora briofítica del área de estudio.
Regulation of Wnt signaling is crucial for embryonic development and adult homeostasis. Here we study the role of Syndecan-4 (SDC4), a cell-surface heparan sulphate proteoglycan, and Fibronectin ...(FN), in Wnt/β-catenin signaling. Gain- and loss-of-function experiments in mammalian cell lines and Xenopus embryos demonstrate that SDC4 and FN inhibit Wnt/β-catenin signaling. Epistatic and biochemical experiments show that this inhibition occurs at the cell membrane level through regulation of LRP6. R-spondin 3, a ligand that promotes canonical and non-canonical Wnt signaling, is more prone to potentiate Wnt/β-catenin signaling when SDC4 levels are reduced, suggesting a model whereby SDC4 tunes the ability of R-spondin to modulate the different Wnt signaling pathways. Since SDC4 has been previously related to non-canonical Wnt signaling, our results also suggest that this proteoglycan can be a key component in the regulation of Wnt signaling.
Full text
Available for:
GEOZS, IJS, IMTLJ, KILJ, KISLJ, NUK, OILJ, PNG, SAZU, SBCE, SBJE, UL, UM, UPCLJ, UPUK
In a high-throughput RNA sequencing analysis, comparing the transcriptional response between Xenopus laevis regenerative and non-regenerative stages to spinal cord injury, cornifelin was found among ...the most highly differentially expressed genes. Cornifelin is mainly expressed in stratified squamous epithelia, but its expression in the spinal cord and other central nervous structures has only been described during early development.
Here, we report cornifelin expression in the spinal cord, retina, and cornea throughout metamorphosis and in the spinal cord after injury. Cornifelin was detected in the grey matter and meninges of the spinal cord from NF-50 to NF-66, with decreased expression in the grey matter during metamorphosis. In the retina, cornifelin was expressed in the ganglion cell layer, the inner and outer nuclear layer, and the outer segment from NF-50 to NF-66. After spinal cord injury, we only observed cornifelin upregulation in NF-66 but no significant changes in NF-50. However, we found cornifelin positive cells in NF-50 meninges closing the spinal cord stumps 1 day after injury and delineating the borders of the spinal cord following the continuity of tissue regeneration in the following days after injury. Instead, in NF-66, cornifelin positive cells were distributed to the ventral side of the spinal cord at 6 days after injury, and at the injury gap at 10 days after injury.
Cornifelin is expressed in the Xenopus laevis spinal cord and eye during metamorphosis and plays a role in the meningeal response to spinal cord injury.
Full text
Available for:
GEOZS, IJS, IMTLJ, KILJ, KISLJ, NLZOH, NUK, OILJ, PNG, SAZU, SBCE, SBJE, UILJ, UL, UM, UPCLJ, UPUK, ZAGLJ, ZRSKP