Your search keyword '"Voß, S."' showing total 9 results

1. Positional plasticity in regenerating Amybstoma mexicanum limbs is associated with cell proliferation and pathways of cellular differentiation

Author

McCusker, Catherine D, Athippozhy, Antony, Diaz-Castillo, Carlos, Fowlkes, Charless, Gardiner, David M, and Voss, S Randal

Subjects

Biological Sciences, Ecology, Regenerative Medicine, Stem Cell Research - Nonembryonic - Non-Human, Stem Cell Research, 1.1 Normal biological development and functioning, Underpinning research, Generic health relevance, Ambystoma mexicanum, Animals, Cell Differentiation, Cell Plasticity, Cell Proliferation, Extremities, Limb Buds, Regeneration, Signal Transduction, Limb regeneration, Positional information, Plasticity, Intercalation, Differentiation, Extracellular matrix, Microarray, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences, Health sciences

Abstract

BackgroundThe endogenous ability to dedifferentiate, re-pattern, and re-differentiate adult cells to repair or replace damaged or missing structures is exclusive to only a few tetrapod species. The Mexican axolotl is one example of these species, having the capacity to regenerate multiple adult structures including their limbs by generating a group of progenitor cells, known as the blastema, which acquire pattern and differentiate into the missing tissues. The formation of a limb regenerate is dependent on cells in the connective tissues that retain memory of their original position in the limb, and use this information to generate the pattern of the missing structure. Observations from recent and historic studies suggest that blastema cells vary in their potential to pattern distal structures during the regeneration process; some cells are plastic and can be reprogrammed to obtain new positional information while others are stable. Our previous studies showed that positional information has temporal and spatial components of variation; early bud (EB) and apical late bud (LB) blastema cells are plastic while basal-LB cells are stable. To identify the potential cellular and molecular basis of this variation, we compared these three cell populations using histological and transcriptional approaches.ResultsHistologically, the basal-LB sample showed greater tissue organization than the EB and apical-LB samples. We also observed that cell proliferation was more abundant in EB and apical-LB tissue when compared to basal-LB and mature stump tissue. Lastly, we found that genes associated with cellular differentiation were expressed more highly in the basal-LB samples.ConclusionsOur results characterize histological and transcriptional differences between EB and apical-LB tissue compared to basal-LB tissue. Combined with our results from a previous study, we hypothesize that the stability of positional information is associated with tissue organization, cell proliferation, and pathways of cellular differentiation.

Published

2015

2. Characterization of in vitro transcriptional responses of dorsal root ganglia cultured in the presence and absence of blastema cells from regenerating salamander limbs.

Author

Athippozhy, Antony, Lehrberg, Jeffrey, Monaghan, James R, Gardiner, David M, and Voss, S Randal

Subjects

Mexican axolotl, axolotl, blastema, dorsal root ganglia, limb regeneration, nerve

Abstract

During salamander limb regeneration, nerves provide signals that induce the formation of a mass of proliferative cells called the blastema. To better understand these signals, we developed a blastema-dorsal root ganglia (DRG) co-culture model system to test the hypothesis that nerves differentially express genes in response to cues provided by the blastema. DRG with proximal and distal nerve trunks were isolated from axolotls (Ambystoma mexicanum), cultured for five days, and subjected to microarray analysis. Relative to freshly isolated DRG, 1,541 Affymetrix probe sets were identified as differentially expressed and many of the predicted genes are known to function in injury and neurodevelopmental responses observed for mammalian DRG. We then cultured 5-day DRG explants for an additional five days with or without co-cultured blastema cells. On Day 10, we identified 27 genes whose expression in cultured DRG was significantly affected by the presence or absence of blastema cells. Overall, our study established a DRG-blastema in vitro culture system and identified candidate genes for future investigations of axon regrowth, nerve-blastema signaling, and neural regulation of limb regeneration.

Published

2014

3. Activation of germline-specific genes is required for limb regeneration in the Mexican axolotl

Author

Zhu, Wei, Pao, Gerald M, Satoh, Akira, Cummings, Gillian, Monaghan, James R, Harkins, Timothy T, Bryant, Susan V, Voss, S Randal, Gardiner, David M, and Hunter, Tony

Subjects

Genetics, Stem Cell Research - Nonembryonic - Non-Human, Regenerative Medicine, Stem Cell Research, 1.1 Normal biological development and functioning, Underpinning research, Ambystoma mexicanum, Amino Acid Sequence, Animals, Argonaute Proteins, Cell Differentiation, Cell Proliferation, Extremities, Gene Expression Regulation, Developmental, Gene Knockdown Techniques, Germ Cells, Molecular Sequence Data, Morpholinos, Regeneration, Wound Healing, Axolotl, Limb regeneration, Germline-like, Piwi-like, Biological Sciences, Medical and Health Sciences, Developmental Biology

Abstract

The capacity for tissue and organ regeneration in humans is dwarfed by comparison to that of salamanders. Emerging evidence suggests that mechanisms learned from the early phase of salamander limb regeneration-wound healing, cellular dedifferentiation and blastemal formation-will reveal therapeutic approaches for tissue regeneration in humans. Here we describe a unique transcriptional fingerprint of regenerating limb tissue in the Mexican axolotl (Ambystoma mexicanum) that is indicative of cellular reprogramming of differentiated cells to a germline-like state. Two genes that are required for self-renewal of germ cells in mice and flies, Piwi-like 1 (PL1) and Piwi-like 2 (PL2), are expressed in limb blastemal cells, the basal layer keratinocytes and the thickened apical epithelial cap in the wound epidermis in the regenerating limb. Depletion of PL1 and PL2 by morpholino oligonucleotides decreased cell proliferation and increased cell death in the blastema leading to a significant retardation of regeneration. Examination of key molecules that are known to be required for limb development or regeneration further revealed that FGF8 is transcriptionally downregulated in the presence of the morpholino oligos, indicating PL1 and PL2 might participate in FGF signaling during limb regeneration. Given the requirement for FGF signaling in limb development and regeneration, the results suggest that PL1 and PL2 function to establish a unique germline-like state that is associated with successful regeneration.

Published

2012

4. Towards comparative analyses of salamander limb regeneration.

Author

Dwaraka, Varun B. and Voss, S. Randal

Subjects

SALAMANDERS, COMPARATIVE studies, TETRAPODS

Abstract

Among tetrapods, only salamanders can regenerate their limbs and tails throughout life. This amazing regenerative ability has attracted the attention of scientists for hundreds of years. Now that large, salamander genomes are beginning to be sequenced for the first time, omics tools and approaches can be used to integrate new perspectives into the study of tissue regeneration. Here we argue the need to move beyond the primary salamander models to investigate regeneration in other species. Salamanders at first glance come across as a phylogenetically conservative group that has not diverged greatly from their ancestors. While salamanders do present ancestral characteristics of basal tetrapods, including the ability to regenerate limbs, data from fossils and data from studies that have tested for species differences suggest there may be considerable variation in how salamanders develop and regenerate their limbs. We review the case for expanded studies of salamander tissue regeneration and identify questions and approaches that are most likely to reveal commonalities and differences in regeneration among species. We also address challenges that confront such an initiative, some of which are regulatory and not scientific. The time is right to gain evolutionary perspective about mechanisms of tissue regeneration from comparative studies of salamander species. Research Highlights: Salamander limb regeneration has been studied using relatively few species.Salamanders as a group present many examples of homoplasy.Studies of additional species will likely identify mechanistic variations in limb regeneration. [ABSTRACT FROM AUTHOR]

Published

2021

5. Transcriptional correlates of proximal-distal identify and regeneration timing in axolotl limbs.

Author

Randal Voss, S., Murrugarra, David, Jensen, Tyler B., and Monaghan, James R.

Subjects

*TRANSCRIPTION factors, *AXOLOTLS, *CELL proliferation, *GENE expression, *BIOMECHANICS

Abstract

Cells within salamander limbs retain memories that inform the correct replacement of amputated tissues at different positions along the length of the arm, with proximal and distal amputations completing regeneration at similar times. We investigated the possibility that positional memory is associated with variation in transcript abundances along the proximal-distal limb axis. Transcripts were deeply sampled from Ambystoma mexicanum limbs at the time they were administered fore arm vs upper arm amputations, and at 19 post-amputation time points. After amputation and prior to regenerative outgrowth, genes typically expressed by differentiated muscle cells declined more rapidly in upper arms while cell cycle transcripts were expressed more highly. These and other expression patterns suggest upper arms undergo more robust tissue remodeling and cell proliferation responses after amputation, and thus provide an explanation for why the overall time to complete regeneration is similar for proximal and distal amputations. Additionally, we identified candidate positional memory genes that were expressed differently between fore and upper arms that encode a surprising number of epithelial proteins and a variety of cell surface, cell adhesion, and extracellular matrix molecules. Also, genes were discovered that exhibited different, bivariate patterns of gene expression between fore and upper arms, implicating dynamic transcriptional regulation for the first time in limb regeneration. Finally, 43 genes expressed differently between fore and upper arm samples showed similar transcriptional patterns during retinoic acid-induced reprogramming of fore arm blastema cells into upper arm cells. Our study provides new insights about the basis of positional information in regenerating axolotl limbs. [ABSTRACT FROM AUTHOR]

Published

2018

6. Gene expression during the first 28 days of axolotl limb regeneration I: Experimental design and global analysis of gene expression.

Author

Voss, S. Randal, Palumbo, Alex, Nagarajan, Radha, Gardiner, David M., Muneoka, Ken, Stromberg, Arnold J., and Athippozhy, Antony T.

Subjects

*AXOLOTLS, *GENE expression, *LIMB regeneration, *MICROARRAY technology, *DEVELOPMENTAL biology, *REGENERATION (Biology)

Abstract

While it is appreciated that global gene expression analyses can provide novel insights about complex biological processes, experiments are generally insufficiently powered to achieve this goal. Here we report the results of a robust microarray experiment of axolotl forelimb regeneration. At each of 20 post-amputation time points, we estimated gene expression for 10 replicate RNA samples that were isolated from 1 mm of heterogeneous tissue collected from the distal limb tip. We show that the limb transcription program diverges progressively with time from the non-injured state, and divergence among time adjacent samples is mostly gradual. However, punctuated episodes of transcription were identified for five intervals of time, with four of these coinciding with well-described stages of limb regeneration-amputation, early bud, late bud, and pallet. The results suggest that regeneration is highly temporally structured and regulated by mechanisms that function within narrow windows of time to coordinate transcription within and across cell types of the regenerating limb. Our results provide an integrative framework for hypothesis generation using this complex and highly informative data set. [ABSTRACT FROM AUTHOR]

Published

2015

7. Probability of regenerating a normal limb after bite injury in the Mexican axolotl ( Ambystoma mexicanum).

Author

Thompson, Sierra, Muzinic, Laura, Muzinic, Christopher, Niemiller, Matthew L., and Voss, S. Randal

Subjects

AMBYSTOMA mexicanum, AXOLOTLS, ANIMAL models of wound healing, LIMB regeneration, TREATMENT for bites & stings, WOUNDS & injuries

Abstract

Multiple factors are thought to cause limb abnormalities in amphibian populations by altering processes of limb development and regeneration. We examined adult and juvenile axolotls ( Ambystoma mexicanum) in the Ambystoma Genetic Stock Center (AGSC) for limb and digit abnormalities to investigate the probability of normal regeneration after bite injury. We observed that 80% of larval salamanders show evidence of bite injury at the time of transition from group housing to solitary housing. Among 717 adult axolotls that were surveyed, which included solitary-housed males and group-housed females, approximately half presented abnormalities, including examples of extra or missing digits and limbs, fused digits, and digits growing from atypical anatomical positions. Bite injury probably explains these limb defects, and not abnormal development, because limbs with normal anatomy regenerated after performing rostral amputations. We infer that only 43% of AGSC larvae will present four anatomically normal looking adult limbs after incurring a bite injury. Our results show regeneration of normal limb anatomy to be less than perfect after bite injury. [ABSTRACT FROM AUTHOR]

Published

2014

8. Retrotransposon long interspersed nucleotide element-1 (LINE-1) is activated during salamander limb regeneration.

Author

Zhu, Wei, Kuo, Dwight, Nathanson, Jason, Satoh, Akira, Pao, Gerald M., Yeo, Gene W., Bryant, Susan V., Voss, S. Randal, Gardiner, David M., and Hunter, Tony

Subjects

RETROTRANSPOSONS, SALAMANDERS, LIMB regeneration, NUCLEOTIDES, CELL differentiation, GENE silencing, RNA

Abstract

Salamanders possess an extraordinary capacity for tissue and organ regeneration when compared to mammals. In our effort to characterize the unique transcriptional fingerprint emerging during the early phase of salamander limb regeneration, we identified transcriptional activation of some germline-specific genes within the Mexican axolotl ( Ambystoma mexicanum) that is indicative of cellular reprogramming of differentiated cells into a germline-like state. In this work, we focus on one of these genes, the long interspersed nucleotide element-1 ( LINE-1) retrotransposon, which is usually active in germ cells and silent in most of the somatic tissues in other organisms. LINE-1 was found to be dramatically upregulated during regeneration. In addition, higher genomic LINE-1 content was also detected in the limb regenerate when compared to that before amputation indicating that LINE-1 retrotransposition is indeed active during regeneration. Active LINE-1 retrotransposition has been suggested to have a potentially deleterious impact on genomic integrity. Silencing of activated LINE-1 by small RNAs has been reported to be part of the machinery aiming to maintain genomic integrity. Indeed, we were able to identify putative LINE-1-related pi RNAs in the limb blastema. Transposable element-related pi RNAs have been identified frequently in the germline in other organisms. Thus, we present here a scenario in which a unique germline-like state is established during axolotl limb regeneration, and the re-activation of LINE-1 may serve as a marker for cellular dedifferentiation in the early-stage of limb regeneration. [ABSTRACT FROM AUTHOR]

Published

2012

9. Comparative transcriptomics of limb regeneration: Identification of conserved expression changes among three species of Ambystoma.

Author

Dwaraka, Varun B., Smith, Jeramiah J., Woodcock, M. Ryan, and Voss, S. Randal

Subjects

*SPECIES, *WOUND healing, *FOREST regeneration, *SALAMANDERS, *EXTREMITIES (Anatomy), *GENE expression, *MUSCLE growth, *AMPUTATION

Abstract

Transcriptome studies are revealing the complex gene expression basis of limb regeneration in the primary salamander model – Ambystoma mexicanum (axolotl). To better understand this complexity, there is need to extend analyses to additional salamander species. Using microarray and RNA-Seq, we performed a comparative transcriptomic study using A. mexicanum and two other ambystomatid salamanders: A. andersoni, and A. maculatum. Salamanders were administered forelimb amputations and RNA was isolated and analyzed to identify 405 non-redundant genes that were commonly, differentially expressed 24 h post amputation. Many of the upregulated genes are predicted to function in wound healing and developmental processes, while many of the downregulated genes are typically expressed in muscle. The conserved transcriptional changes identified in this study provide a high-confidence dataset for identifying factors that simultaneous orchestrate wound healing and regeneration processes in response to injury, and more generally for identifying genes that are essential for salamander limb regeneration. • Salamanders may owe their amazing ability to regenerate limbs to highly conserved transcriptional programs. • We identified 405 CRGs among three ambystomatid species that are commonly, differently expressed after limb amputation. • The CRGs identified in this study present a high-confidence set of biomarkers for future studies of tissue regeneration. [ABSTRACT FROM AUTHOR]

Published

2019