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Deposition And Dislocation Of Pottery As Surface Assemblages In Semi-arid RegionsTuncer, Aylin 01 February 2005 (has links) (PDF)
This thesis aims to discuss the archaeological concerns about how surveys can provide data tht is meaningful to construct spatial patterning and its intricacies for inferences through altering processes diversified as cultural and natural processes. Along with that there is also a second concern dealing with the application of these theoretical issues to practical basis. It consists both methodological limits and also limits governed by the legislation of the particular area according to the aim of the study. A particular space, semi-arid climate is selected for comparing the amount of attrition and accretion caused by natural factors, to be able to apply the studies to Anatolian geography. However applications from around the world are frequently discussed here, these are mainly the case studies bringing methodological scheme for the appropriate data collection.
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Spatio-temporal control of the cytosolic redox environment in C. elegansRomero, Catalina 10 October 2015 (has links)
Compartmentalization of redox reactions is essential to all life forms. Protein activity can respond to changes in the local redox environment through the reversible oxidation of cysteine thiols. For the majority of cysteines in the proteome, this interaction takes place through equilibration with the glutathione pool; this raises the question whether this redox pool acts as a buffer, or instead as a sensitive media, transducing information from a local physiological state into protein function.
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Electromagnetism, Site Formation, and Conflict Event Theory at the San Jacinto Battleground and Washington-on-the-Brazos, TexasPertermann, Dana Lee 2011 August 1900 (has links)
Conflict Event theory has the potential to change how archaeologists investigate battlefield sites. As a theoretical paradigm, eventful archaeology allows us to give agency to social-structure changing events, going beyond collect artifacts after the battle is over. Coupled with site formation processes, this model allows us to project battle elements to re-create the historical events that occurred at conflict sites. Within this theoretical framework, we can begin to understand why the conflict unfolded in a particular manner. Two site of the Texian Revolution are particularly appropriate to this new theoretical model: the San Jacinto Battleground (SJB), the location of the last battle of the Texian Revolution, and Washington-on-the-Brazos (WOB), the location of the signing of the Texas Declaration of Independence.
Merging this theoretical model with an investigation of site formation processes (understanding the matrix in which the artifacts lie) and pulse-domain electromagnetic surveying allows for a much more robust approach to Battlefield Archaeology. Pulse-induction allows for the detection of discrete artifacts in the soil, and is a much more reliable method than the more commonly used magnetometry. Analyzing characteristics of the soil surrounding the artifacts then gives us a third line of inquiry as to why artifacts are in certain locations in the archaeological record, allowing for an explanation as to their quality and quantity.
La teoría del Acontecimiento del conflicto tiene el potencial para cambiar cómo arqueólogos investigan sitios de campo de batalla. Como un paradigma teórico, la arqueología llena de acontecimientos nos permite dar agencia a la social-estructura que cambia acontecimientos, yendo más allá de reúne artefactos después de que la batalla esté sobre. Asociado con procesos de formación de sitio, este modelo nos permite proyectar batalla elementos para recrear los acontecimientos históricos que ocurrieron en sitios de conflicto. Dentro de esta armazón teórica, nosotros podemos comenzar a comprender por qué el conflicto desplegó en una manera particular. Dos sitio de la Revolución de Texian es especialmente apropiado a este nuevo modelo teórico: el San Campo de batalla de Jacinto (SJB), la ubicación de la última batalla de la Revolución de Texian, y de Washington en el Brazos (WOB), la ubicación del firmar de la Declaración de Tejas de Independencia. Unir este modelo teórico con una investigación de sitúa procesos de formación (comprendiendo la matriz en la que los artefactos están) y el pulso-dominio inspeccionar electromagnético tiene en cuenta un enfoque mucho más robusto a la Arqueología del Campo de batalla. La pulso-inducción tiene en cuenta el descubrimiento de artefactos distintos en la tierra, y es un método mucho más seguro que el magnetometry más comúnmente utilizado. Analizar características de la tierra que rodea los artefactos entonces nos dan una tercera línea de indagación en cuanto a por qué artefactos están en ciertas ubicaciones en el registro arqueológico, teniendo en cuenta una explicación en cuanto a su calidad y la cantidad.
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Patterning of stem cells during limb regeneration in Ambystoma mexicanumRönsch, Kathleen 22 January 2018 (has links) (PDF)
Axolotl uniquely generates blastema cells as a pool of progenitor/stem cells to restore an entire limb, a particular property that other organisms, such as humans, do not have. What underlies these differences? Is the main difference that cells residing at the amputation plane (in the stump) undergo reprogramming processes to re-enter the embryonic program, which allows developmental patterning to start, or are there fundamental differences? There is also a significant debate about whether regeneration occurs via stem cell differentiation or by dedifferentiation of mature limb tissue. The aim of my thesis was to address following questions: Are the cells in the blastema reprogrammed or differentiated to regenerate? Are the blastema cells genetically reactivated de novo during regeneration? How does the amputated limb exactly know which part of the limb needs to be regenerate?
Using a novel technique of long-term genetic fate mapping, my team demonstrated that dedifferentiation in regenerated axolotl muscle tissue does not occur. Instead, PAX7+ satellite cells indeed play an important role during muscle regeneration in the axolotl limb. Surprisingly, this is in contrast to the newt, which regenerates muscle cells through a dedifferentiation process. Therefore, there is a fundamental difference that underlies the regenerative mechanism ((Sandoval-Guzman et al., 2014) [KR1]). This demonstrates that there is an unexpected diversity and flexibility of cellular mechanims used during limb regeneration, even among two closely related species. Finally, if one salamander species uses a mammalian regenerative strategy (Cornelison and Wold, 1997; Collins et al., 2005) involving stem cells and another uses a dedifferentiative strategy, this raises the question of whether there are other fundamental aspects of regeneration that could also be anomalous. This hypothesis is promising since there could be more than one possible mechanism to induce mammalian regeneration.
The process of limb regeneration in principle seems to be more similar to those of limb development as historically assumed. We showed molecularly that embryonic players are reused during regeneration by reactivating the position- and tissue-specific developmental gene programs by using the newly isolated Twist sequences as early blastema cell markers ((Kragl et al., 2013) [KR2]). To gain insights into the molecular mechanisms of the P/D limb patterning in general, it was crucial to study the early patterning events of the resident progenitor/stem cells by using the specific blastema cell marker HoxA as a positional marker along the proximo-distal axis. Our HOXA protein analysis using high molecular and cellular resolution as well as transplantation assays demonstrated for the first time that axolotl limb blastema cells acquire their positional identity in a proximal to distal sequence. We found a hierarchy of cellular restrictions in positional identities. Amputation at the level of the upper arm showed that the blastema harbors cells, which convert to lower arm and hand. We observed ((Roensch et al., 2013) [KR3]) for the first time that intercalation- the intermediate element (lower arm) arises later from an interaction between the proximal and distal cells identities- does not occur. Intercalation, which has been an accepted model for a long time, is not the patterning mechanism underlying normal (without any manipulation) limb regeneration that is unique to axolotl. We further demonstrated, using the Hox genes as markers that positional identity is cell-type specific since their effects were confirmed to be present in the lateral plate mesoderm- derived cells of the limb.
As our knowledge about limb blastemas expands concerning cell composition and molecular events controlling patterning, the similarity to development is becoming more and more clear. My work has resolved many ambiguities surrounding the molecularly identification of different types of blastema cells and how P/D limb patterning occurs during regeneration in comparison to development. It has highlighted the importance of combining high-resolution methods, such as in situ hybridizations, single-cell PCR (sc-PCR) of individual dissociated blastema cells and genetic labeling methods with grafting experiments to map cell fates in vivo.
In addition to understanding the processes of regeneration, another long-term goal in the regenerative medicine field is to identify key molecules that trigger the regeneration of tissues. Recently, my colleague Takuji Sugiura (Sugiura et al., 2016) observed that an early event of blastema formation is the secretion of molecules like MLP (MARCKS-like protein), which induces wound-associated cell cycle re-entry. Such findings further increase the enthusiasm of biologists to understand the underlying principles of regeneration. By building our knowledge of the molecules and pathways that are involved in tissue regeneration, we increase the possibility of identifying a way to ‘activate’ regenerative processes in humans and thus reach the final goal of regenerative medicine, which is to use the concepts of cellular reprogramming, stem cell biology and tissue engineering to repair complex body structures.
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Patterning of stem cells during limb regeneration in Ambystoma mexicanumRönsch, Kathleen 30 November 2017 (has links)
Axolotl uniquely generates blastema cells as a pool of progenitor/stem cells to restore an entire limb, a particular property that other organisms, such as humans, do not have. What underlies these differences? Is the main difference that cells residing at the amputation plane (in the stump) undergo reprogramming processes to re-enter the embryonic program, which allows developmental patterning to start, or are there fundamental differences? There is also a significant debate about whether regeneration occurs via stem cell differentiation or by dedifferentiation of mature limb tissue. The aim of my thesis was to address following questions: Are the cells in the blastema reprogrammed or differentiated to regenerate? Are the blastema cells genetically reactivated de novo during regeneration? How does the amputated limb exactly know which part of the limb needs to be regenerate?
Using a novel technique of long-term genetic fate mapping, my team demonstrated that dedifferentiation in regenerated axolotl muscle tissue does not occur. Instead, PAX7+ satellite cells indeed play an important role during muscle regeneration in the axolotl limb. Surprisingly, this is in contrast to the newt, which regenerates muscle cells through a dedifferentiation process. Therefore, there is a fundamental difference that underlies the regenerative mechanism ((Sandoval-Guzman et al., 2014) [KR1]). This demonstrates that there is an unexpected diversity and flexibility of cellular mechanims used during limb regeneration, even among two closely related species. Finally, if one salamander species uses a mammalian regenerative strategy (Cornelison and Wold, 1997; Collins et al., 2005) involving stem cells and another uses a dedifferentiative strategy, this raises the question of whether there are other fundamental aspects of regeneration that could also be anomalous. This hypothesis is promising since there could be more than one possible mechanism to induce mammalian regeneration.
The process of limb regeneration in principle seems to be more similar to those of limb development as historically assumed. We showed molecularly that embryonic players are reused during regeneration by reactivating the position- and tissue-specific developmental gene programs by using the newly isolated Twist sequences as early blastema cell markers ((Kragl et al., 2013) [KR2]). To gain insights into the molecular mechanisms of the P/D limb patterning in general, it was crucial to study the early patterning events of the resident progenitor/stem cells by using the specific blastema cell marker HoxA as a positional marker along the proximo-distal axis. Our HOXA protein analysis using high molecular and cellular resolution as well as transplantation assays demonstrated for the first time that axolotl limb blastema cells acquire their positional identity in a proximal to distal sequence. We found a hierarchy of cellular restrictions in positional identities. Amputation at the level of the upper arm showed that the blastema harbors cells, which convert to lower arm and hand. We observed ((Roensch et al., 2013) [KR3]) for the first time that intercalation- the intermediate element (lower arm) arises later from an interaction between the proximal and distal cells identities- does not occur. Intercalation, which has been an accepted model for a long time, is not the patterning mechanism underlying normal (without any manipulation) limb regeneration that is unique to axolotl. We further demonstrated, using the Hox genes as markers that positional identity is cell-type specific since their effects were confirmed to be present in the lateral plate mesoderm- derived cells of the limb.
As our knowledge about limb blastemas expands concerning cell composition and molecular events controlling patterning, the similarity to development is becoming more and more clear. My work has resolved many ambiguities surrounding the molecularly identification of different types of blastema cells and how P/D limb patterning occurs during regeneration in comparison to development. It has highlighted the importance of combining high-resolution methods, such as in situ hybridizations, single-cell PCR (sc-PCR) of individual dissociated blastema cells and genetic labeling methods with grafting experiments to map cell fates in vivo.
In addition to understanding the processes of regeneration, another long-term goal in the regenerative medicine field is to identify key molecules that trigger the regeneration of tissues. Recently, my colleague Takuji Sugiura (Sugiura et al., 2016) observed that an early event of blastema formation is the secretion of molecules like MLP (MARCKS-like protein), which induces wound-associated cell cycle re-entry. Such findings further increase the enthusiasm of biologists to understand the underlying principles of regeneration. By building our knowledge of the molecules and pathways that are involved in tissue regeneration, we increase the possibility of identifying a way to ‘activate’ regenerative processes in humans and thus reach the final goal of regenerative medicine, which is to use the concepts of cellular reprogramming, stem cell biology and tissue engineering to repair complex body structures.
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