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The development and ultrastructure of intergeneric nuclear transfer embryos using ovine ooplasm.Hamilton, Hamish MacDonald January 2005 (has links)
Title page, table of contents and abstract only. The complete thesis in print form is available from the University of Adelaide Library. / This thesis encompasses work that aimed to further understand genomic reprogramming, an event crucial in obtaining development in cloned embryos produced by somatic cell nuclear transfer (SCNT). An increasing number of different mammalian species have been cloned using nuclear transfer technology since Dolly the cloned sheep was first successfully produced. However, the biological mechanisms involved in the process of nuclear reprogramming are yet to be fully described. At the centre of this study was an intergeneric SCNT model, which was implemented to determine whether reprogramming factors are conserved across genera. The interaction between donor nucleus and recipient ooplasm was characterised with regard to developmental potential, timing of genome activation, nucleolus formation, and expression of significant proteins. In initial studies, fusion parameters of the intergeneric SCNT procedure were optimised for the ovine cytoplast and porcine donor granulosa cell. Cell fusion and lysis percentages were determined over a range of electrical pulse voltage, duration and repetition. The optimal electrofusion settings were a single DC pulse of 1.5 kV/cm for 20 usec following a 2 sec 400 kHz alignment pulse. In addition, it was demonstrated that ovine oocytes were sensitive to electric stimulation to the extreme that oocyte activation would occur no matter how low the voltage. The practical significance was that it would not be possible to implement a fusion before activation protocol. The ability of the ooplasm of one species to replicate chromosomes and support early embryo cleavage was determined in a preliminary experiment where intergeneric embryos were produced by SCNT using bovine and ovine foetal fibroblasts, and ovine ooplasm. After their construction, the embryos were allowed to develop for 7 days in vitro and the developmental stage determined by Hoechst staining and nuclei counting. In addition, chromosome spreads of the ovine and bovine somatic foetal fibroblast cell lines used in SCNT, as well as the intra- and intergeneric SCNT embryos were prepared to determine whether the ovine ooplasm was replicating the chromosomes according to the karyotype of the donor nucleus. The somatic cells were karyotyped with 54 and 60 chromosomes counted for ovine and bovine cells respectively. Bovine-ovine embryos were characterised as having a bovine karyotype as distinct from an ovine karyotype, due to the presence of only two metacentric chromosomes as compared with six that are found in the latter. These preliminary results indicated that bovine nuclei obtained from foetal fibroblast cells could initiate early pre-implantation embryo development with the support of ovine oocyte cytoplasm. The development of a proportion (33%) of ovine-ovine intrageneric SCNT embryos beyond the 16-cell stage indicated that an extensive characterisation of an intergeneric model could be performed satisfactorily. It was hypothesised that the ovine ooplasm would possess the ability to direct in vitro preimplantation embryo development after nuclear transfer using donor nuclei from a different genus, as has been demonstrated in studies using bovine and rabbit ooplasm. In this study, intergeneric SCNT embryos were constructed by the separate fusion of porcine and bovine cells with ovine cytoplasts (bovine-ovine and porcine-ovine respectively), cultured in vitro and the developmental characteristics compared with ovine-ovine SeNT embryos as well as ovine in vitro produced (IVP) embryos. These four groups of embryos were sampled to determine embryo cell numbers at 24, 36, 48, 72, 96, 120 and 168 h post-activation to compare development over time. Despite cleaving normally and undergoing the first three cleavage divisions at a rate comparable with ovine-ovine SCNT embryos, a major block in development occurred in the intergeneric embryos at the 8-16 cell stage. Consequently, no blastocyst formation was obtained as observed for the IVP and ovine-ovine SCNT controls. These results indicate that unlike the rabbit and bovine ooplasm, the ovine ooplasm is not suitable for intergeneric reprogramming of somatic nuclei from another genus, at least of porcine or bovine origin. To determine the effect of a less differentiated donor nucleus on intergeneric developmental potential, embryonic cell nuclear transfer (ECNT) was conducted in a separate experiment by fusing pluripotent bovine and ovine donor cells (obtained from day-4 preimplantation embryos) to ovine cytoplasts. After 7 days of culture, the cell number of embryos was determined by Hoechst staining and fluorescent observation. Despite observing a single bovine-ovine blastocyst (4.8%), the developmental block remained at the 8-16 cell stage of development. This outcome indicates that a less differentiated nucleus does not increase intergeneric developmental capability. It is well documented that the ooplasm supplies a large amount of mRNA and protein to the newly formed embryo, crucial for normal development leading up to the major activation of the embryonic genome. However, the interaction between the ooplasm as compared with the donor nucleus in SCNT embryos during this developmental period is poorly understood. This intergeneric SCNT model provided an opportunity to determine the role of the ooplasm on nucleolus formation, which is a marker for genome activation. Ultrastructural evidence was obtained that indicates the ovine ooplasm directs the initial assembly of the nucleolus independent of the species of the nuclear donor. Intergeneric porcine-ovine SCNT and intrageneric ovine-ovine SCNT embryos were constructed and the nucleolus ultrastructure and nucleolus associated rRNA synthesis examined in 1-,2-,4-, early 8-, late 8-and 16-cell embryos using transmission electron microscopy (TEM) and light microscopical autoradiography. Intergeneric porcine-ovine SCNT embryos exhibited nucleolar precursor bodies (NPBs) of an ovine (ruminant) ultrastructure, but no active rRNA producing fibrillogranular nucleoli at any of the stages. Unusually, cytoplasmic organelles were located inside the nucleus of two porcineovine SCNT embryos. The ovine-ovine SCNT embryos, on the other hand, revealed fibrillogranular nucleoli in 16-cell embryos. In parallel, autoradiographic labelling over the nucleoplasm and, in particular, the nulcleoli was detected. Bovine-ovine SCNT embryos at the 8-cell stage were examined for nucleolar morphology and exhibited ruminant-type NPBs as well as structures that appeared to comprise of broken down fibrillar material, perhaps formerly of nucleolar origin from the donor cell. These observations indicate that factors within the ovine ooplasm are playing a role in the initial assembly of the embryonic nucleolus in intrageneric SCNT embryos. To further characterise nucleolus formation, immunocytochemical localisation by confocal microscopy of nucleolin, fibrillarin and RNA polymerase, three key proteins involved in processing rRNA transcripts, was performed on early 8-, late 8- and 16-cell embryos for ovineovine and porcine-ovine SCNT embryos. Nucleolin was localised throughout the nucleoplasm for all developmental stages examined in porcine-ovine and ovine-ovine SCNT embryos and, in particular, intensity around the presumptive nucleolar compartments in the later developmental stages. Fibrillarin and RNA polymerase I, on the other hand, were not detected in any ovineovine or porcine-ovine SCNT embryos or ovine IVP controls, although both proteins were detected in control bovine IVP blastocysts. This result indicates that the antifibrillarin and anti-RNA polymerase I were not compatible with the ovine form of these respective proteins. As nucleolin is not present in porcine in vivo embryos before the major activation of the embryonic genome, its presence in porcine-ovine SCNT embryo nucleus indicates that nucleolin is derived from the abundant protein and mRNA stored in the ovine ooplasm. The intergeneric SCNT model established in this thesis demonstrates that the ovine ooplasm lacks the ability to support embryonic development beyond the 16-cell stage. The TEM and autoradiographical studies, in combination with the protein immunocytochemistry study, confirmed that these embryos are unable to undergo the major activation of the embryonic genome, and that the ooplasm influences the initial nucleolar assembly in these embryos. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1167553 / Thesis (Ph.D.) -- University of Adelaide, School of Agriculture and Wine, 2005
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Assessment of Microchimerism Following Somatic Cell Nuclear Transfer and Natural Pregnancies in Goats (<i>Capra aegagrus hircus</i>)Gash, Kirsten Karen 01 August 2018 (has links)
Somatic cell nuclear transfer (SCNT) is a powerful tool for production of transgenic animals for various biomedical and agricultural applications. For instance, our group is using SCNT to produce transgenic goats to study the role of cardiac fibrosis in initiation and progression of atrial fibrillation. There is a possibility of cell transfer from a transgenic fetus to its non-transgenic surrogate mother, known as fetal microchimerism; from a transgenic mother to non-transgenic fetus, maternal microchimerism and from a transgenic twin to non-transgenic twin in utero. Initially, we have assessed the presence of fetal microchimerism in tissue samples from non-transgenic surrogates that delivered transgenic SCNT generated offspring. Then, the SCNT derived transgenic goats were naturally bred and non-transgenic offspring were used for the assessment of maternal microchimerism. Additionally, fetal-fetal microchimerism was evaluated using the tissue samples from non-transgenic twins of transgenic offspring. We investigated DNA from kidney, liver, lung, lymph node and spleen for the presence of neomycin resistant gene (Neo), which all transgenic SCNT generated females and their transgenic offspring tested positive for. We found no detectable maternal or fetal-fetal microchimerism, but fetal microchimerism was detected in lymph node of one of the surrogate dams that carried a SCNT pregnancy. The results of the study have direct implications on the use and disposal of non-transgenic surrogates and non-transgenic offspring.
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Molecular reprogramming in bovine embryos after serial somatic cell chromatin transferRodriguez-Osorio, Nelida 03 May 2008 (has links)
Somatic Cell Nuclear Transfer (SCNT), commonly known as cloning, is the transfer of a somatic nucleus into an enucleated oocyte to produce a clone. The chromatin structure of somatic cells permits the expression of certain genes, while silencing the rest of the genome. The cytoplasm of oocytes can reprogram a somatic nucleus by reactivating the genes necessary for embryonic development and silencing the somatic genes. However, the low efficiency of SCNT indicates that successful nuclear reprogramming is a rare event. The objectives of this study were determine the extent of transcriptional reprogramming in bovine blastocysts produced by serial rounds of chromatin transfer (from first and fourth generations), using blastocysts produced by in vitro fertilization (IVF) as controls, to identify cumulative errors in the transcriptome profile. Differentially expressed genes were studied further to determine their function in embryonic development. We identified a set of transcripts consistently misregulated in cloned blastocyst, some of which had a more marked misregulation in the embryos produced by 4 successive rounds of cloning. Among the genes significantly upregulated in both CT groups compared to IVF blastocysts were both de novo DNA methylation enzymes DNMT3A and DNMT3B. Expression patterns, structural and functional analyses were performed for DNA methyltransferases. A high structural and functional conservation was observed for DNA methyltransferases among human, mouse, and bovine species. A set of genes that participate in early embryonic development, chromatin remodeling and DNA methylation were differentially regulated in cloned embryos and had not been fully annotated at the time of the analysis. We annotated those genes and submitted them to the Bovine Genome Sequencing Consortium database. These results have important implications for the selection of models for the study of DNA methylation during early development. The present study provides a valuable data set for identifying possible cumulative errors in somatic cell chromatin transfer that could hinder nuclear reprogramming shedding light on the epigenetic role in reprogramming and cell plasticity.
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Reprogramming DNA Methylation in Bovine Cells by Knocking Down DNA Methyltransferase-1 with RNA InterferenceStroud, Todd 20 January 2010 (has links)
Embryos derived by somatic cell nuclear transfer (SCNT) produce few
pregnancies that result in a live, healthy offspring. This has largely been attributed to the
aberrant reprogramming of the somatic cell DNA used for cloning. In order to improve
the efficiency of cloning there is a great deal of research needed to determine the role of
proteins involved in early embryonic reprogramming. In addition, studies are needed to
determine effects on somatic and embryonic cell development as a result of altering
these proteins.
In this study we investigate the use of RNA interference in bovine somatic cells
and embryos to knock down the expression of DNA methyltransferase-1 (DNMT1), an
enzyme responsible for maintenance methylation in mammalian cells. We designed our
experiments to test whether or not knocking down the DNMT1 gene would lead to a
decrease in global methylation. It is our hypothesis that using somatic cells with reduced
methylation may be advantageous for increasing the efficiency of cloning via somatic
cell nuclear transfer. To accomplish this task, we have designed an infectious non-replicating lentiviral
vector capable of delivering a gene that produces a short hairpin RNA targeting the
mRNA of DNMT1. The construct included a sequence coding for green fluorescent
protein (GFP) that will allow us to identify cells expressing the hairpin as well as a
region coding for neomycin resistance so we could select for a pure population of
transgenic cells to use for analysis.
Infecting bovine fetal fibroblast cells with genes encoding shRNAs that target
DNMT1 was successful. Quantitative real time PCR analysis of DNMT1 mRNA
suggests that our shRNAs are capable of an 80% knockdown. The protein blot of
indicates up to 90% knockdown of DNMT1. Cells transduced twice with a high titer
virus showed the highest knockdown of both DNMT1 mRNA and the protein. Analysis
of immunolabeled cytosine methylaiton showed a global decrease in DNA methylation
as a result of the DNMT1 knockdown. However, double transduced cells with a high
knockdown percentage of DNMT1 mRNA and protein became hypermethylated.
The second experiment was conducted to determine the effect of injecting small
interfering RNAs (siRNAs) targeting DNMT1 into oocytes prior to parthenogenic
activation. This experiment was designed to give us information on the survivability and
epigenetic profile of early embryos with decreased DNMT1. Oocytes injected with
siRNA targeting DNMT1 had little development past the 8-cell stage as compared to the
sham injected oocytes. This treatment group also had decreased DNA methylation as
determined by immunolabeling of methylated cytosine residues.
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Contribuição ao estudo da hematologia de bezerros da raça nelore, originados por meio da técnica de transferência nuclear de célula somática (TNCS) - Clonagem / Contribution to the study of hematology of Nelore calves produced by somatic cell nuclear transferKomninou, Eliza Rossi 22 August 2008 (has links)
A presente pesquisa teve a finalidade de estudar a hematologia de bezerros clonados da raça Nelore, originados por meio da técnica de transferência nuclear de células somáticas (TNCS) por meio da avaliação do quadro eritrocitário, da dinâmica dos tipos de hemoglobina e do metabolismo do ferro destes animais durante o primeiro mês de vida. O delineamento experimental envolveu a colheita de 260 amostras de sangue e soro sanguíneo de 20 bezerros distribuídas nos seguintes momentos: imediatamente após o nascimento, 12 horas após o nascimento, 1 dia de vida, 2 , 3 , 4, 5, 7, 10, 15, 20 e 30 dias de vida. Os animais foram divididos em quatro grupos experimentais: 12 bezerros obtidos por meio da técnica de TNCS pelos laboratórios A e 8, 4 por meio de fertilização in vitro (FIV) e 4 por monta natural (MN). A ocorrência de anemia de grau moderado a grave, do tipo normocítico e normocrômico, foi observada em 100 % (5/5) dos 5 bezerros clonados pelo Laboratório A, enquanto a incidência nos bezerros clonados pelo Laboratório B foi igual a 14,2 % (1/7), nos bezerros obtidos por fertilização in vitro foi igual 50,0 % (2/4) e em bezerros obtidos por monta natural foi igual a 50,0 % (2/4). A avaliação do eritrograma dos bezerros cio nados pelo Laboratório A evidenciou que a anemia instalou-se gradualmente a partir das 12 horas de vida atingindo ao final da primeira semana, a, sua intensidade máxima, sendo observada a recuperação gradativa dos valores eritrograma a partir do 15°dia de vida. Os valores médios obtidos para o eritrograma dos bezerros clonados do Laboratório A no 7º dia de vida foram os seguintes: Hemácias - 4,33X106/mm3-; Volume Globular - 23 %, Taxa de Hemoglobina - 7,25 g/dL; VCM - 52,89 µ3-; HCM - 16,65 pg; CHCM - 31,47%. A anemia observada nos bezerros clonados pelo Laboratório A era de origem ferropriva, pois se evidenciou nesses animais uma significativa diminuição dos teores séricos de ferro associada à diminuição do índice de saturação da transferrina (1ST), enquanto os valores da capacidade total de ligação do ferro (CTLF) não sofreram influência durante o período. Os valores médios obtidos para o metabolismo de ferro dos bezerros clonados pelo Laboratório A no 7º dia de vida foram os seguintes: teores séricos de ferro - 47,35 mg/dL; capacidade total de ligação de ferro - 455,90 mg/dL, índice de saturação da transferrina - 9,64%. Durante o estudo dos tipos de hemoglobinas, utilizando-se técnica de eletroforese foram identificados três fenótipos de hemoblogina adulta (Hb-A; Hb-B e Hb-AB) e a presença de hemoglobina fetal (Hb-F), não sendo observadas anomalias que pudessem sugerir a ocorrência de hemoglobinopatias hereditárias e/ ou congênitas. Verificou-se que as taxas de Hb-A, nos clones com fenótipo Hb-AB e Hb-A, permaneceram estáveis durante todo o período experimental, enquanto nos bezerros obtidos por fertilização in vitro ou monta natural com os mesmos fenótipos (Hb-A e Hb-AB) observou-se a partir de 120 horas de vida um gradativo aumento das taxas de Hb-A. Durante a avaliação da dinâmica da hemoglobina do tipo fetal (Hb-F) no primeiro mês de vida observou-se, que todos os grupos animais apresentaram comportamento similar, caracterizado por sua diminuição com o desenvolvimento etário. / The present work aimed to study the hematology of cloned Nelore calves produced using the technique of somatic cell nuclear transfer (SCNT), by evaluating erythrocyte parameters, hemoglobin dynamics, and iron metabolism in the animals during the first month after birth. The experimental design included the collection of 260 blood and blood serum samples from 20 calves in the following times: immediately after birth, 12 hours after birth, 1st of life, 2nd, 3rd, 4th, 5th, 7th, 20th and 30th day of life. The animals were classified in four experimental groups: 12 calves produced, using SCNT for two commercial laboratories (laboratory A=5 calves and laboratory B= 7 calves), four calves produced by in vitro fertilization (IVF) and four calves produced by natural mating (NM). Mild to severe normocytic and normochromic anemia was observed in 100% (5/5) cloned calves from laboratory A, and 14.2% (117) cloned calves from laboratory B. In both IVF and NM calves, anemia was observed in 50% (214) of the calves. Erytrogram evaluation of cloned calves from laboratory A showed that anemia developed gradually from 12 hours after birth, was most intense at the end of the first week, and then erytrogram normal values were recovered after the 15th day of life. Mean values for the laboratory A cloned calves erytrogram in the 7th day of life were the following: Red cells 4033X106/mm3, hematocrit 23%, hemoglobin 7.25g/dL, MCV 52.89µ3-; MCH 16.65, MCHC 31.47%. Anemia observed in cloned calves from laboratory A was caused by iron deficiency, since a significant decrease in iron se rum levels together with a decrease in transferrin saturation index (TSI) was confirmed. At the same time, Total iron-binding capacity (TIBC) was not changed in this period of time. Mean iron metabolism values for cloned calves from laboratory A were the following: serum iron amount: 47,35mg/dL, TIBC 455,90 mg/dL and TSI 9,64%. Hemoglobin identification by eletrophoresis identified three adult hemolglobin phenotypes (A-Hb; B-Hb e AB-Hb) and the fetal hemoglobin (F-HB), and there was no sign of hereditary hemoglobin disorders were observed. The rate of A-Hb in cloned calves with A-Hb and AB-Hb phenotypes was maintained during the experimental period. Nonetheless, for the IVF calves with the same phenotypes (A-Hb and AB-Hb) a constant increase in the A-Hb was noticed. For the evaluation of F-Hb dynamics in the first month of life, results showed similar pattern, characterized by its decrease with age.
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Contribuição ao estudo da hematologia de bezerros da raça nelore, originados por meio da técnica de transferência nuclear de célula somática (TNCS) - Clonagem / Contribution to the study of hematology of Nelore calves produced by somatic cell nuclear transferEliza Rossi Komninou 22 August 2008 (has links)
A presente pesquisa teve a finalidade de estudar a hematologia de bezerros clonados da raça Nelore, originados por meio da técnica de transferência nuclear de células somáticas (TNCS) por meio da avaliação do quadro eritrocitário, da dinâmica dos tipos de hemoglobina e do metabolismo do ferro destes animais durante o primeiro mês de vida. O delineamento experimental envolveu a colheita de 260 amostras de sangue e soro sanguíneo de 20 bezerros distribuídas nos seguintes momentos: imediatamente após o nascimento, 12 horas após o nascimento, 1 dia de vida, 2 , 3 , 4, 5, 7, 10, 15, 20 e 30 dias de vida. Os animais foram divididos em quatro grupos experimentais: 12 bezerros obtidos por meio da técnica de TNCS pelos laboratórios A e 8, 4 por meio de fertilização in vitro (FIV) e 4 por monta natural (MN). A ocorrência de anemia de grau moderado a grave, do tipo normocítico e normocrômico, foi observada em 100 % (5/5) dos 5 bezerros clonados pelo Laboratório A, enquanto a incidência nos bezerros clonados pelo Laboratório B foi igual a 14,2 % (1/7), nos bezerros obtidos por fertilização in vitro foi igual 50,0 % (2/4) e em bezerros obtidos por monta natural foi igual a 50,0 % (2/4). A avaliação do eritrograma dos bezerros cio nados pelo Laboratório A evidenciou que a anemia instalou-se gradualmente a partir das 12 horas de vida atingindo ao final da primeira semana, a, sua intensidade máxima, sendo observada a recuperação gradativa dos valores eritrograma a partir do 15°dia de vida. Os valores médios obtidos para o eritrograma dos bezerros clonados do Laboratório A no 7º dia de vida foram os seguintes: Hemácias - 4,33X106/mm3-; Volume Globular - 23 %, Taxa de Hemoglobina - 7,25 g/dL; VCM - 52,89 µ3-; HCM - 16,65 pg; CHCM - 31,47%. A anemia observada nos bezerros clonados pelo Laboratório A era de origem ferropriva, pois se evidenciou nesses animais uma significativa diminuição dos teores séricos de ferro associada à diminuição do índice de saturação da transferrina (1ST), enquanto os valores da capacidade total de ligação do ferro (CTLF) não sofreram influência durante o período. Os valores médios obtidos para o metabolismo de ferro dos bezerros clonados pelo Laboratório A no 7º dia de vida foram os seguintes: teores séricos de ferro - 47,35 mg/dL; capacidade total de ligação de ferro - 455,90 mg/dL, índice de saturação da transferrina - 9,64%. Durante o estudo dos tipos de hemoglobinas, utilizando-se técnica de eletroforese foram identificados três fenótipos de hemoblogina adulta (Hb-A; Hb-B e Hb-AB) e a presença de hemoglobina fetal (Hb-F), não sendo observadas anomalias que pudessem sugerir a ocorrência de hemoglobinopatias hereditárias e/ ou congênitas. Verificou-se que as taxas de Hb-A, nos clones com fenótipo Hb-AB e Hb-A, permaneceram estáveis durante todo o período experimental, enquanto nos bezerros obtidos por fertilização in vitro ou monta natural com os mesmos fenótipos (Hb-A e Hb-AB) observou-se a partir de 120 horas de vida um gradativo aumento das taxas de Hb-A. Durante a avaliação da dinâmica da hemoglobina do tipo fetal (Hb-F) no primeiro mês de vida observou-se, que todos os grupos animais apresentaram comportamento similar, caracterizado por sua diminuição com o desenvolvimento etário. / The present work aimed to study the hematology of cloned Nelore calves produced using the technique of somatic cell nuclear transfer (SCNT), by evaluating erythrocyte parameters, hemoglobin dynamics, and iron metabolism in the animals during the first month after birth. The experimental design included the collection of 260 blood and blood serum samples from 20 calves in the following times: immediately after birth, 12 hours after birth, 1st of life, 2nd, 3rd, 4th, 5th, 7th, 20th and 30th day of life. The animals were classified in four experimental groups: 12 calves produced, using SCNT for two commercial laboratories (laboratory A=5 calves and laboratory B= 7 calves), four calves produced by in vitro fertilization (IVF) and four calves produced by natural mating (NM). Mild to severe normocytic and normochromic anemia was observed in 100% (5/5) cloned calves from laboratory A, and 14.2% (117) cloned calves from laboratory B. In both IVF and NM calves, anemia was observed in 50% (214) of the calves. Erytrogram evaluation of cloned calves from laboratory A showed that anemia developed gradually from 12 hours after birth, was most intense at the end of the first week, and then erytrogram normal values were recovered after the 15th day of life. Mean values for the laboratory A cloned calves erytrogram in the 7th day of life were the following: Red cells 4033X106/mm3, hematocrit 23%, hemoglobin 7.25g/dL, MCV 52.89µ3-; MCH 16.65, MCHC 31.47%. Anemia observed in cloned calves from laboratory A was caused by iron deficiency, since a significant decrease in iron se rum levels together with a decrease in transferrin saturation index (TSI) was confirmed. At the same time, Total iron-binding capacity (TIBC) was not changed in this period of time. Mean iron metabolism values for cloned calves from laboratory A were the following: serum iron amount: 47,35mg/dL, TIBC 455,90 mg/dL and TSI 9,64%. Hemoglobin identification by eletrophoresis identified three adult hemolglobin phenotypes (A-Hb; B-Hb e AB-Hb) and the fetal hemoglobin (F-HB), and there was no sign of hereditary hemoglobin disorders were observed. The rate of A-Hb in cloned calves with A-Hb and AB-Hb phenotypes was maintained during the experimental period. Nonetheless, for the IVF calves with the same phenotypes (A-Hb and AB-Hb) a constant increase in the A-Hb was noticed. For the evaluation of F-Hb dynamics in the first month of life, results showed similar pattern, characterized by its decrease with age.
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Modificações epigenéticas da cromatina e sua relação com a reprogramação nuclear de bovinos / Epigenetic modifications of chromatin and their relation with the nuclear reprogramming of bovineSampaio, Rafael Vilar 31 March 2015 (has links)
A reprogramação nuclear de uma célula somática a um estado embrionário tem diversas aplicações, como pesquisas básicas na biologia do desenvolvimento, terapia celular, melhoramento genético em animais de produção e conservação de espécies. As principais técnicas utilizadas para a reprogramação nuclear são a transferência nuclear de células somáticas (TNCS) e a geração de células tronco pluripotente induzidas (iPS). Muitos trabalhos têm mostrado uma baixa eficiência no processo de reprogramação nuclear nas duas técnicas, além disso, modificações epigenéticas tem sido apontada como a principal barreira para uma reprogramação nuclear eficiente. Por esse motivo, medidas como a utilização de células menos diferenciadas e/ou alteração do perfil epigenético das células somáticas podem aumentar a eficiência destas técnicas. Por isso, o objetivo deste trabalho foi investigar a influência de marcas epigenéticas em células bovinas utilizadas na reprogramação nuclear mediada por TNCS ou superexpressão de genes relacionados a pluripotêcia (iPS). Para isso, utilizamos 3 abordagens. Primeiro, analisamos marcações epigenéticas relacionadas ao desenvolvimento embrionário e pluripotência (H3K9me2, H3K9me3, H3K9ac, 5mC e 5hmC) em diferentes tipos celulares, analisamos a expressão gênica de genes responsáveis por essas marcações em células de diferentes tecidos (ex. células tronco mesenquimais (MSC) e fibroblastos) e as utilizamos como doadoras de núcleo na TNCS. Na segunda e a terceira abordagem, utilizamos células com menores níveis de H3K9me2 para a geração de iPS e na TNCS, respectivamente. Além disso, por se mostrar eficiente na TNCS, analisamos o efeito da sincronização do ciclo celular por privação de soro fetal bovino (SFB) na geração de células iPS. Com o intuito de diminuir os níveis de H3K9me2, as células foram tratadas com UNC0638, um inibidor especifico das metiltransferases de histona G9a/GLP. Nossos resultados do primeiro experimento mostraram que as MSC podem ser utilizadas como doadoras de núcleo na TNCS, no entanto, mesmo com algumas diferenças na expressão gênica em relação aos fibroblastos, a produção de blastocistos não foi diferente entre as duas células. No segundo experimento, as células privadas de SFB geraram mais colônias que as células controle, enquanto que as células tratadas não apresentaram diferença. Por último, as células tratadas com o UNC0638 apresentaram um menor nível de metilação no DNA em zigotos em relação às células controle. Os resultados encontrados neste trabalho podem contribuir para o melhor entendimento dos mecanismos epigenéticos envolvidos na reprogramação nuclear de bovinos / Nuclear reprogramming of somatic cells to embryonic state has several aplications, such as basic research on developmental biology, cell therapy, genetic improvement in livestock animals and preservation of endangered species. The principal techniques utilized to achieve nuclear reprogramming are Somatic Cell Nuclear Transfer (SCNT) and induced pluripotency. Several works has reported low efficiency rates of nuclear reprogramming when these techniques are used to reprogram somatic cells. Moreover, epigenetic modifications acquired during development act as epigenetic barrier to the complete reprogramming process. For this reason, strategies such as use of less differentiated cells and/or modification of epigenetic profile of somatic cells might increase the efficiency these techniques. The objective of this work was investigate the influence of epigenetic marks in bovine cells utilized on nuclear reprogramming experiments mediated by SCNT or induced pluripotency. To investigate it, we used three approaches. First, we analyzed the epigenetic marks related to the embryonic development and pluripotency (e.g H3K9me2, H3K9me3, H3K9ac, 5mC and 5hmC), gene expression of genes involved in these epigenetic marks in different tissues (i.e. mesenchymal stem cells (MSC) and fibroblasts) and their use as nuclear donor cells on SCNT procedure. Regarding the second and the third approach, we utilized cells with reduced levels of H3K9me2 to generate iPS cells and cloned embryos, respectively. Furthermore, since serum starvation has been demonstrated increase SCNT developmental rates, we assessed the effect of cell cycle synchronization mediated by serum starvation on nuclear reprogramming using iPS cells. Aiming decrease the levels of H3K9me2, cells were treated with UNC0638, a chemical probe that works as a specific inhibitor of the histone methyltransferases G9a and its counterpartner GLP. Our results showed that MSC are suitable to be used as nuclear donors on SCNT procedures, however, in spite of differences on gene expression comparing with fibroblasts, the embryonic developmental rates were not improved. On the second experiment, cells privated of fetal calf serum produced more iPS cells colonies than control cells, whereas cells treated with UNC did not show differences when compared with untreated cells. Lastly, UNC treated donor cells treated produced cloned zygotes with lower levels of DNA methylation compared to zygotes derivated from untreated cells. The results presented here will contribute to the better understanding of the epigenetic mechanisms involved on bovine nuclear reprogramming
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Modificações epigenéticas da cromatina e sua relação com a reprogramação nuclear de bovinos / Epigenetic modifications of chromatin and their relation with the nuclear reprogramming of bovineRafael Vilar Sampaio 31 March 2015 (has links)
A reprogramação nuclear de uma célula somática a um estado embrionário tem diversas aplicações, como pesquisas básicas na biologia do desenvolvimento, terapia celular, melhoramento genético em animais de produção e conservação de espécies. As principais técnicas utilizadas para a reprogramação nuclear são a transferência nuclear de células somáticas (TNCS) e a geração de células tronco pluripotente induzidas (iPS). Muitos trabalhos têm mostrado uma baixa eficiência no processo de reprogramação nuclear nas duas técnicas, além disso, modificações epigenéticas tem sido apontada como a principal barreira para uma reprogramação nuclear eficiente. Por esse motivo, medidas como a utilização de células menos diferenciadas e/ou alteração do perfil epigenético das células somáticas podem aumentar a eficiência destas técnicas. Por isso, o objetivo deste trabalho foi investigar a influência de marcas epigenéticas em células bovinas utilizadas na reprogramação nuclear mediada por TNCS ou superexpressão de genes relacionados a pluripotêcia (iPS). Para isso, utilizamos 3 abordagens. Primeiro, analisamos marcações epigenéticas relacionadas ao desenvolvimento embrionário e pluripotência (H3K9me2, H3K9me3, H3K9ac, 5mC e 5hmC) em diferentes tipos celulares, analisamos a expressão gênica de genes responsáveis por essas marcações em células de diferentes tecidos (ex. células tronco mesenquimais (MSC) e fibroblastos) e as utilizamos como doadoras de núcleo na TNCS. Na segunda e a terceira abordagem, utilizamos células com menores níveis de H3K9me2 para a geração de iPS e na TNCS, respectivamente. Além disso, por se mostrar eficiente na TNCS, analisamos o efeito da sincronização do ciclo celular por privação de soro fetal bovino (SFB) na geração de células iPS. Com o intuito de diminuir os níveis de H3K9me2, as células foram tratadas com UNC0638, um inibidor especifico das metiltransferases de histona G9a/GLP. Nossos resultados do primeiro experimento mostraram que as MSC podem ser utilizadas como doadoras de núcleo na TNCS, no entanto, mesmo com algumas diferenças na expressão gênica em relação aos fibroblastos, a produção de blastocistos não foi diferente entre as duas células. No segundo experimento, as células privadas de SFB geraram mais colônias que as células controle, enquanto que as células tratadas não apresentaram diferença. Por último, as células tratadas com o UNC0638 apresentaram um menor nível de metilação no DNA em zigotos em relação às células controle. Os resultados encontrados neste trabalho podem contribuir para o melhor entendimento dos mecanismos epigenéticos envolvidos na reprogramação nuclear de bovinos / Nuclear reprogramming of somatic cells to embryonic state has several aplications, such as basic research on developmental biology, cell therapy, genetic improvement in livestock animals and preservation of endangered species. The principal techniques utilized to achieve nuclear reprogramming are Somatic Cell Nuclear Transfer (SCNT) and induced pluripotency. Several works has reported low efficiency rates of nuclear reprogramming when these techniques are used to reprogram somatic cells. Moreover, epigenetic modifications acquired during development act as epigenetic barrier to the complete reprogramming process. For this reason, strategies such as use of less differentiated cells and/or modification of epigenetic profile of somatic cells might increase the efficiency these techniques. The objective of this work was investigate the influence of epigenetic marks in bovine cells utilized on nuclear reprogramming experiments mediated by SCNT or induced pluripotency. To investigate it, we used three approaches. First, we analyzed the epigenetic marks related to the embryonic development and pluripotency (e.g H3K9me2, H3K9me3, H3K9ac, 5mC and 5hmC), gene expression of genes involved in these epigenetic marks in different tissues (i.e. mesenchymal stem cells (MSC) and fibroblasts) and their use as nuclear donor cells on SCNT procedure. Regarding the second and the third approach, we utilized cells with reduced levels of H3K9me2 to generate iPS cells and cloned embryos, respectively. Furthermore, since serum starvation has been demonstrated increase SCNT developmental rates, we assessed the effect of cell cycle synchronization mediated by serum starvation on nuclear reprogramming using iPS cells. Aiming decrease the levels of H3K9me2, cells were treated with UNC0638, a chemical probe that works as a specific inhibitor of the histone methyltransferases G9a and its counterpartner GLP. Our results showed that MSC are suitable to be used as nuclear donors on SCNT procedures, however, in spite of differences on gene expression comparing with fibroblasts, the embryonic developmental rates were not improved. On the second experiment, cells privated of fetal calf serum produced more iPS cells colonies than control cells, whereas cells treated with UNC did not show differences when compared with untreated cells. Lastly, UNC treated donor cells treated produced cloned zygotes with lower levels of DNA methylation compared to zygotes derivated from untreated cells. The results presented here will contribute to the better understanding of the epigenetic mechanisms involved on bovine nuclear reprogramming
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Personhood and Cloning: Modern Applications and Ethics of Stem Cell and Cloning TechnologyMcCarrey, Sariah Cottrell 05 July 2013 (has links) (PDF)
Within many communities and religions, including the LDS community, there is some controversy surrounding the use of stem cells – particularly embryonic stem cells (ESC). Much of this controversy arises from confusion and misconceptions about what stem cells actually are, where they come from , and when life begins. The theology of the Church of Jesus Christ of Latter-day Saints has interesting implications for the last of these considerations, and it becomes less a question of “when does life begin” and more an exploration of “when does personhood begin” or “when does the spirit enter the body.” With no official Church stance, statements from Church leaders vary on this topic, and this first section of the thesis explores the philosophical and practical meaning of personhood with a biological background intended for those not familiar with the origin or uses of stem cells.The second portion of the thesis explores possible cloning technologies. Recent events and advances address the possibility of cloning endangered and extinct species. The ethics of these types of cloning have considerations uniquely different from the type of cloning commonly practiced. Cloning of cheetahs (and other endangered or vulnerable species) may be ethically appropriate, given certain constraints. However, the ethics of cloning extinct species varies; for example, cloning mammoths and Neanderthals is more ethically problematic than conservation cloning, and requires more attention. Cloning Neanderthals in particular is likely unethical and such a project should not be undertaken. It is important to discuss and plan for the constraints necessary to mitigate the harms of conservation and extinct cloning, and it is imperative that scientific and public discourse enlighten and guide actions in the sphere of cloning.
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Controle epigenético do gene imprinted SNRPN durante o desenvolvimento e reprogramação nuclear em equídeos / Epigenetic control of the SNRPN imprinted gene during developmental and nuclear reprogramming in equidsRigoglio, Nathia Nathaly 15 March 2016 (has links)
A tranferência nuclear de células somáticas (TNCS) está sendo utilizada para produzir cavalos de elite. No entanto, durante este procedimento pode ocorrer a perfuração da zona pelúcida, levando, ocasionalmente, à secção da massa celular interna, e conseqüente derivação de gêmeos monozigóticos. Além de serem relatadas alterações no processo de imprinting genômico, que conduzem ao desenvolvimento de doenças. Com a descoberta da possibilidade de reprogramar as células somáticas a um estado de pluripotência (iPSCs), estas células passaram a ser muito utilizadas em pesquisas de neurociência. Contudo, também ocorrem modificações epigenéticas durante esta reprogramação celular. Portanto, nossas hipóteses são que os gêmeos eqüinos gerados pela TNCS podem levar às irregularidades no desenvolvimento do sistema nervoso. O padrão de metilação do SNRPN nas estruturas dos fetos muares clonados, e as células iPSCs são diferentes dos padrões encontrados nos muares analisados. A expressão dos genes SNRPN, Necdin e UBE3A são maiores no cérebro, enquanto a expressão do H19 é maior nas membranas extra-embrionárias. Em nosso estudo, obtivemos duas gestações gemelares equinas derivadas da TNCS, que foram interrompidas com 40 e 60 dias de gestação, e comparados com gestações eqüinas únicas de idade similar. Diferenças no comprimento entre os embriões gêmeos foram observadas aos 40 (2.0 e 2.2 cm 10%) e aos 60 (6,5 e 8,5 cm 24%) dias de gestação. Somente o plexo coróide do quarto ventrículo apresentou-se mais desenvolvido nos fetos com maior comprimento. Ao analisarmos fetos muares clonados em diferentes idades gestacionais e compará-los com muares, nos períodos embrionário, fetal e adulto, não foi observada diferença no padrão de metilação do gene SNRPN. No entanto, na décima passagem das células iPSC o padrão de metilação alterou, em relação aos muares estudados e ao padrão observado nos fibroblastos. Ao analisarmos os fetos clonados nas diferentes idades gestacionais observou-se no cérebro menor expressão dos gene H19 e UBE3A, e maior expressão do gene SNRPN. Contudo, a expressão do gene Necdin variou entre as estruturas estudadas. Em conclusão, apesar dos gêmeos eqüinos provenientes de TNCS diferirem quanto ao tamanho, morfologicamente são iguais. Dentre as estruturas cerebrais o plexo coróide se apresentou mais desenvolvido nos fetos de maior comprimento. Os fetos muares clonados não apresentaram diferença no padrão de metilação do gene SNRPN. No entanto, as iPSCs apresentaram alteração no padrão de metilação deste gene na décima passagem. Embora os genes SNRPN, Necdin e UBE3A sejam expressos no cérebro, o SNRPN apresentou-se prevalente nessa estrutura / The nuclear transfer of somatic cells (SCNT) is being used to produce elite horses. However, during this procedure can occur drilling of the zona pellucida, leading occasionally to the section of the inner cell mass, and subsequent derivation of monozygotic twins. Besides being related changes in genomic imprinting process, leading to the development of diseases. With the discovery of the possibility to reprogram somatic cells to a pluripotent state (iPSCs), these cells have become widely used in neuroscience research. However, also occur epigenetic changes during this cellular reprogramming. Therefore, our hypothesis is that equine twins caused by equine ART could lead to developmental irregularities of the nervous system. The patterns of SNRPN methylation in the structures of cloned mule fetuses and in iPSCs are different from the patterns found in the analyzed mules. And the expression of SNRPN, Necdin and UBE3A genes are higher in the brain, while the higher expression of H19 gene occurs in the extraembryonic membranes. In our study we derived two equine twin SCNT pregnancies that were interrupted at 40 and 60 days of gestation and compared to singleton fetuses of similar age. Differences in lengths between twin embryos were observed at both 40 (2.0 and 2.2 cm 10%) and 60 (6.5 and 8.5 cm 24%) days of gestation. Only the choroid plexus in the fourth ventricle more developed in the twins with the greatest length. Analyzing mules cloned fetuses at different gestational ages, and compare them with mules at embryonic, fetal and adult period; there was no difference in the pattern of methylation in SNRPN gene. However, in the tenth passage of the iPSCs the methylation pattern was altered in relation to the studied mules and the pattern observed in fibroblasts. When the cloned fetuses at different gestational ages were analyzed, the brain presented lower expression of H19 and UBE3A genes, and higher expression of SNRPN gene. However, the expression of Necdin gene varied among the structures studied. In conclusion, despite the twin horses from SCNT differ in size, they are morphologically identical. Among the brain structures the choroid plexus performed more developed in the fetuses of greater length. Cloned mules fetuses showed no difference in the pattern of methylation SNRPN gene. However, iPSCs have changes in the pattern of methylation of this gene in the tenth passage. Although SNRPN, Necdin and Ube3A genes are expressed in the brain, SNRPN is prevalent in this structure
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