A Clonal Analysis of Zebrafish Heart Morphogenesis and Regeneration

Gupta, Vikas

January 2014

<p>As vertebrate embryos grow and develop into adults, their organs must acquire mass and mature tissue architecture to maintain proper homeostasis. While juvenile growth encompasses a significant portion of life, relatively little is known about how individual cells proliferate, with respect to one another, to orchestrate this final maturation. For its simplicity and ease of genetic manipulations, the teleost zebrafish (Danio rerio) was used to understand how the proliferative outputs of individual cells generate an organ from embryogenesis into adulthood. </p><p>To define the proliferative outputs of individual cells, a multicolor clonal labeling approach was taken that visualized a large number of cardiomyocyte clones within the zebrafish heart. This Brainbow technique utilizes Cre-loxP mediated recombination to assign cells upwards of ~90 unique genetic tags. These tags are comprised of the differential expression of 3 fluorescent proteins, which combine to give rise to spectrally distinct colors that represent these genetic tags. Tagging of individual cardiomyocytes was induced early in development, when the wall of the cardiac ventricle is a single myocyte thick. Single cell cardiomyocyte clones within this layer expanded laterally in a developmentally plastic manner into patches of variable shapes and sizes as animals grew into juveniles. As maturation continued into adulthood, a new lineage of cortical muscle appeared at the base of the ventricle and enveloped the ventricle in a wave of proliferation that fortified the wall to make it several myocytes thick. This outer cortical layer was formed from a small number (~8) of dominant cortical myocyte clones that originated from trabecular myocytes. These trabecular myocytes were found to gain access to the ventricular surface through rare breaches within the single cell thick ventricular wall, before proliferating over the surface of the ventricle.</p><p> </p><p>These results demonstrated an unappreciated dynamic juvenile remodeling event that generated the adult ventricular wall. During adult zebrafish heart regeneration, the primary source of regenerating cardiomyocytes stems from this outer wall of muscle. Regenerating cardiomyocytes within this outer layer of muscle are specifically marked by the cardiac transcription factor gene gata4, which they continue to express as they proliferate into the wound area.</p><p>Using heart regeneration to guide investigation of juvenile cortical layer formation, we found that both processes shared similar molecular and tissue specific responses including expression and requirement of gata4. Additional markers suggested that juvenile hearts were under stress and that this stress could play a role to initiate cortical morphogenesis. Indeed, experimental injury or a physiologic increase in stress to juvenile hearts caused the ectopic appearance of cortical muscle, demonstrating that injury could trigger premature morphogenesis.</p><p>These studies detail the cardiomyocyte proliferative events that shape the heart and identify molecular parallels that exist between regeneration and cortical layer formation. They show that adult zebrafish heart regeneration utilizes an injury/stress responsive program that was first used to remodel the heart during juvenile growth.</p> / Dissertation

Developmental biology

Clonal Analysis

Heart Regeneration

Organogenesis

Zebrafish

Clonal Analysis of the Zebrafish Fin Regeneration Blastema

Tornini, Valerie Angela

January 2016

<p>Regeneration is a remarkable feat of developmental regrowth and patterning. The blastema is a mass of progenitor cells that enables complete regeneration of amputated salamander limbs or fish fins. Despite years of study, methodologies to identify and track blastemal cell progenies have been deficient, restricting our understanding of appendage regeneration at a cellular and molecular level. To bridge this knowledge gap, gene expression analysis, the generation of transgenic and mutant zebrafish, qualitative and quantitative analyses, morphological measurements, and chemical treatments were used to assess molecular and cellular processes involved in fin regeneration. Two main findings arose from these methods. The first provides evidence that connective tissue progenitors are rapidly organized into a scalable blueprint of lost structures, and that amputation stimulates resident cells to reset proximodistal positional information. The second identifies a fibroblast subpopulation near uninjured fin joints that contributes to the blastemal progenitor population. These findings reveal insights on cellular and molecular mechanisms of appendage regeneration and provide a basis for work exploring how cells in an adult vertebrate bone appendage coordinately rebuild a new structure.</p> / Dissertation

Developmental biology

Cellular biology

Biology

appendage

blastema

clonal analysis

fin

regeneration

zebrafish

Defining lineage potential and fate behaviour of progenitors during pancreas development

Sznurkowska, Magdalena Katarzyna

January 2018

No description available.

Determining the Role of Wnt5a Signaling in Embryonic Limb Outgrowth via Clonal Analysis

Sowby, Whitney Herrod

14 August 2008

The exact mechanisms that regulate limb outgrowth the mouse embryo are unknown. Although there are several models, we favor a hypothesis where cells become polarized by signals secreted from the AER which orient their cell migration and/or divisions causing limb outgrowth. Clonal analysis has provided a mechanism to study cell behavior. We have generated a targeting construct containing the Fgf8 inhibitor, Sprouty2, in order to generate mutant clones for behavioral analyses in the limb. In order to more effectively study clonal behavior we report the modification of a novel clonal analysis approach, exo-utero surgery. We have modified, enhanced and proven that this technique can be used successfully in mouse embryos in which we directly apply 4-OHtamoxifen to the limb to induce YFP or β-gal reporter genes in limb mesenchyme. Using this method, we can closely control the timing and location of the induced clones and observe cell behavior during embryonic limb development. Phenotypes of Wnt5a-/- and Ror2-/- exhibit shortened limbs suggesting they function in a similar pathway. Wnt5a and Ror have been found to "colocalize" in the growing limb bud and have also been shown to bind in vitro. Here we show preliminary results about Wnt5a and Ror2 in vivo association by immunoprecipitation of limb bud extracts.

limb development

wnt5a

ror2

AER

clonal analysis

Cell and Developmental Biology

Physiology

Quantitative analysis on the origins of morphologically abnormal cells in temporal lobe epilepsy

Singh, Shatrunjai P.

January 2015

No description available.

Nanoscience

Temporal Lobe Epilepsy

Dentate Granule Cells

Clonal Analysis

Quantitative Analysis

Pilocarpine

Neural stem cells

The Systematic Design and Application of Robust DNA Barcodes

Buschmann, Tilo

19 September 2016

High-throughput sequencing technologies are improving in quality, capacity, and costs, providing versatile applications in DNA and RNA research. For small genomes or fraction of larger genomes, DNA samples can be mixed and loaded together on the same sequencing track. This so-called multiplexing approach relies on a specific DNA tag, index, or barcode that is attached to the sequencing or amplification primer and hence accompanies every read. After sequencing, each sample read is identified on the basis of the respective barcode sequence. Alterations of DNA barcodes during synthesis, primer ligation, DNA amplification, or sequencing may lead to incorrect sample identification unless the error is revealed and corrected. This can be accomplished by implementing error correcting algorithms and codes. This barcoding strategy increases the total number of correctly identified samples, thus improving overall sequencing efficiency. Two popular sets of error-correcting codes are Hamming codes and codes based on the Levenshtein distance. Levenshtein-based codes operate only on words of known length. Since a DNA sequence with an embedded barcode is essentially one continuous long word, application of the classical Levenshtein algorithm is problematic. In this thesis we demonstrate the decreased error correction capability of Levenshtein-based codes in a DNA context and suggest an adaptation of Levenshtein-based codes that is proven of efficiently correcting nucleotide errors in DNA sequences. In our adaptation, we take any DNA context into account and impose more strict rules for the selection of barcode sets. In simulations we show the superior error correction capability of the new method compared to traditional Levenshtein and Hamming based codes in the presence of multiple errors. We present an adaptation of Levenshtein-based codes to DNA contexts capable of guaranteed correction of a pre-defined number of insertion, deletion, and substitution mutations. Our improved method is additionally capable of correcting on average more random mutations than traditional Levenshtein-based or Hamming codes. As part of this work we prepared software for the flexible generation of DNA codes based on our new approach. To adapt codes to specific experimental conditions, the user can customize sequence filtering, the number of correctable mutations and barcode length for highest performance. However, not every platform is susceptible to a large number of both indel and substitution errors. The Illumina “Sequencing by Synthesis” platform shows a very large number of substitution errors as well as a very specific shift of the read that results in inserted and deleted bases at the 5’-end and the 3’-end (which we call phaseshifts). We argue in this scenario that the application of Sequence-Levenshtein-based codes is not efficient because it aims for a category of errors that barely occurs on this platform, which reduces the code size needlessly. As a solution, we propose the “Phaseshift distance” that exclusively supports the correction of substitutions and phaseshifts. Additionally, we enable the correction of arbitrary combinations of substitution and phaseshift errors. Thus, we address the lopsided number of substitutions compared to phaseshifts on the Illumina platform. To compare codes based on the Phaseshift distance to Hamming Codes as well as codes based on the Sequence-Levenshtein distance, we simulated an experimental scenario based on the error pattern we identified on the Illumina platform. Furthermore, we generated a large number of different sets of DNA barcodes using the Phaseshift distance and compared codes of different lengths and error correction capabilities. We found that codes based on the Phaseshift distance can correct a number of errors comparable to codes based on the Sequence-Levenshtein distance while offering the number of DNA barcodes comparable to Hamming codes. Thus, codes based on the Phaseshift distance show a higher efficiency in the targeted scenario. In some cases (e.g., with PacBio SMRT in Continuous Long Read mode), the position of the barcode and DNA context is not well defined. Many reads start inside the genomic insert so that adjacent primers might be missed. The matter is further complicated by coincidental similarities between barcode sequences and reference DNA. Therefore, a robust strategy is required in order to detect barcoded reads and avoid a large number of false positives or negatives. For mass inference problems such as this one, false discovery rate (FDR) methods are powerful and balanced solutions. Since existing FDR methods cannot be applied to this particular problem, we present an adapted FDR method that is suitable for the detection of barcoded reads as well as suggest possible improvements.

DNA Barcodes

sample tags

SMRT

single molecule real time sequencing

Fehlerkorrektur

false discovery rate

next generation sequencing

Hochdurchsatzsequenzierung

deep sequencing

multiplexing

clonal analysis

DNA Barcodes

sample tags

SMRT

single molecule real time sequencing

error correction

false discovery rate

next generation sequencing

high throughput sequencing

deep sequencing

multiplexing

clonal analysis

ddc:000

The Systematic Design and Application of Robust DNA Barcodes

Buschmann, Tilo

02 September 2016

High-throughput sequencing technologies are improving in quality, capacity, and costs, providing versatile applications in DNA and RNA research. For small genomes or fraction of larger genomes, DNA samples can be mixed and loaded together on the same sequencing track. This so-called multiplexing approach relies on a specific DNA tag, index, or barcode that is attached to the sequencing or amplification primer and hence accompanies every read. After sequencing, each sample read is identified on the basis of the respective barcode sequence. Alterations of DNA barcodes during synthesis, primer ligation, DNA amplification, or sequencing may lead to incorrect sample identification unless the error is revealed and corrected. This can be accomplished by implementing error correcting algorithms and codes. This barcoding strategy increases the total number of correctly identified samples, thus improving overall sequencing efficiency. Two popular sets of error-correcting codes are Hamming codes and codes based on the Levenshtein distance. Levenshtein-based codes operate only on words of known length. Since a DNA sequence with an embedded barcode is essentially one continuous long word, application of the classical Levenshtein algorithm is problematic. In this thesis we demonstrate the decreased error correction capability of Levenshtein-based codes in a DNA context and suggest an adaptation of Levenshtein-based codes that is proven of efficiently correcting nucleotide errors in DNA sequences. In our adaptation, we take any DNA context into account and impose more strict rules for the selection of barcode sets. In simulations we show the superior error correction capability of the new method compared to traditional Levenshtein and Hamming based codes in the presence of multiple errors. We present an adaptation of Levenshtein-based codes to DNA contexts capable of guaranteed correction of a pre-defined number of insertion, deletion, and substitution mutations. Our improved method is additionally capable of correcting on average more random mutations than traditional Levenshtein-based or Hamming codes. As part of this work we prepared software for the flexible generation of DNA codes based on our new approach. To adapt codes to specific experimental conditions, the user can customize sequence filtering, the number of correctable mutations and barcode length for highest performance. However, not every platform is susceptible to a large number of both indel and substitution errors. The Illumina “Sequencing by Synthesis” platform shows a very large number of substitution errors as well as a very specific shift of the read that results in inserted and deleted bases at the 5’-end and the 3’-end (which we call phaseshifts). We argue in this scenario that the application of Sequence-Levenshtein-based codes is not efficient because it aims for a category of errors that barely occurs on this platform, which reduces the code size needlessly. As a solution, we propose the “Phaseshift distance” that exclusively supports the correction of substitutions and phaseshifts. Additionally, we enable the correction of arbitrary combinations of substitution and phaseshift errors. Thus, we address the lopsided number of substitutions compared to phaseshifts on the Illumina platform. To compare codes based on the Phaseshift distance to Hamming Codes as well as codes based on the Sequence-Levenshtein distance, we simulated an experimental scenario based on the error pattern we identified on the Illumina platform. Furthermore, we generated a large number of different sets of DNA barcodes using the Phaseshift distance and compared codes of different lengths and error correction capabilities. We found that codes based on the Phaseshift distance can correct a number of errors comparable to codes based on the Sequence-Levenshtein distance while offering the number of DNA barcodes comparable to Hamming codes. Thus, codes based on the Phaseshift distance show a higher efficiency in the targeted scenario. In some cases (e.g., with PacBio SMRT in Continuous Long Read mode), the position of the barcode and DNA context is not well defined. Many reads start inside the genomic insert so that adjacent primers might be missed. The matter is further complicated by coincidental similarities between barcode sequences and reference DNA. Therefore, a robust strategy is required in order to detect barcoded reads and avoid a large number of false positives or negatives. For mass inference problems such as this one, false discovery rate (FDR) methods are powerful and balanced solutions. Since existing FDR methods cannot be applied to this particular problem, we present an adapted FDR method that is suitable for the detection of barcoded reads as well as suggest possible improvements.

info:eu-repo/classification/ddc/000

ddc:000