The Maya origin of a Mexican god the iconographic primacy of Tezcatlipoca at Chichén Itzá, Yucatan over Tula, Hidalgo; and its possible derivation from God K--K'awil /

Sullivan, Mark.

January 2009

Thesis (M.A.)--University of Central Florida, 2009. / Adviser: Arlen Chase. Includes bibliographical references (p. 89-110).

Discerning Migration In The Archaeological Record: A Case Study At Chichén Itzá

Slusser, Andrea

01 January 2008

Migration, as a theory to explain aspects in the archaeological record, has fallen out of favor in Mesoamerican archaeology, possibly due to a lack of a standard definition or description of migration. Migration as an explanation of change in Maya civilizations has been around since the 1950's and the culture-history era of American archaeology. Since the early 1990's, migration has been treated as a process, one that can be discerned in pre-literate cultures as well as historical ones. Models of the migration process are being developed and tested. One type of migration, elite dominance migration, is a particularly suitable process to study in Mesoamerica. A model of elite dominance migration might include the following attributes: advance contact by the migrating culture, migration to a center, maintenance of contact with the sending population, spatial concentration of the incoming population, migration of a selected population of elites, and a cause or push factor. To find these attributes, the receiving population is studied to determine if there are multiple changes in the material record consistent with an intrusion of an outside group. And, there should be a rough chronological correlation between the sending and receiving populations. The Maya site of Chichén Itzá is a classic case study, and provides a starting point as a possible receiving population of an elite dominance migration. There is an abundance of scholarship devoted to the question of the relationship between Chichén Itzá and Tula, Hidalgo, in Central Mexico. The iconographic similarities between the two sites are numerous and have been thoroughly discussed in the literature. But, there is much more evidence that should be examined in applying a model of elite dominance, such as architecture, artifacts (including ceramics and obsidian), burial and caching practices, and site configuration. Comparing all of these categories at the two sites, one reaches two conclusions: there are multiple lines of evidence for change in the material record across the spectrum of categories at Chichén Itzá, and, to a lesser extent, at Tula, Hidalgo, indicating a population intrusion. And, secondly, there are abundant similarities in architecture, caching practices, ceramics, and other aspects of the material record that support the assertion of strong contacts between the two sites. Applying the model of elite dominance migration to Chichén Itzá, the majority of the markers for this type of migration can be seen in the material record of the site, as well as the site of Tula, Hidalgo. Chichén Itzá has the attributes of a receiving population, with an elite dominance migration of Central Mexican people taking place there, either from Tula, Hidalgo or from a third, as yet unspecified site that impacted both Chichén Itzá and Tula.

migration

Maya

Chichen Itza

Tula

Anthropology

ROLE OF TULA-FAMILY PROTEINS IN T CELL DRIVEN RESPONSES

Newman, Tiffanny Nicole

January 2011

The TULA-family consists of two proteins implicated in cellular regulation. TULA-1 is expressed in T-cells and is involved in apoptosis. TULA-2 is a ubiquitously expressed phosphatase that suppresses receptor-mediated signaling. T cells from mice lacking TULA-1 and 2 (double knockout, or dKO) are hypersensitive to TCR stimulation. This may be due to these proteins having a similar function working synergistically or dissimilar functions having a convergent effect. To understand functional interaction of these proteins we have characterized TULA-family knockout mice without and during an immune challenge. We show that CD4+ T cells of dKO mice have a characteristic CD45RB distribution, and that within the CD45RBlow subset effector/memory T cells are expanded only in dKO, but not in single knockouts (sKO) of either TULA-1 or TULA-2. However, CD4+ T cells of sKO and wild-type (WT) mice respond differently to TCR stimulation as seen using signaling and responses in vitro. To evaluate consequences of TULA deficiency in vivo, we utilized two mouse models of inflammatory bowel disease: TNBS-induced colitis and colitis induced by the adoptive transfer of CD45RBhigh CD4+ T cells. Studies utilizing TNBS indicate that deficiency of any TULA-family protein exacerbates TNBS-induced colitis. Likewise, dKO CD45RBhigh CD4+ T cells were significantly more colitogenic than cells from WT mice in the transfer model. Taken together, our data indicate that TULA-family proteins are key to the physiological regulation of T-cell reactivity that drives intestinal inflammation. / Microbiology and Immunology

Immunology

Autoimmune

Inflammatory Bowel Disease

Phosphatase

T Cells

Tula-1

Tula-2

Anpassung der landwirtschaftlichen Unternehmensführung an die marktwirtschaftlichen Rahmenbedingungen in der Russischen Föderation - untersucht am Beispiel des Gebiets Tula /

Hunger, Olga.

January 2003

Univ., Diss--Hohenheim, 2003.

The Maya Origin Of A Mexican God: The Iconographic Primacy Of Tezcatlipoca At Chichen Itza, Yucatan Over Tula, Hidalgo; And Its Possible Derivation From God K-k'awil

Sullivan, Mark

01 January 2009

Two long-held views in Mesoamerican research, the Mexican origin of the god Tezcatlipoca and the insinuation of Toltec iconography into the artistic format of Chichen Itza, Yucatan, Mexico, emanating from Tula, Hidalgo, Mexico conditioned this research. Considering Tezcatlipoca to be a Mexican god imparts both a foreign origin for and the preexistence of that god in Central Mexico prior to its manifestation in the sculptural repertoire of Chichen Itza, a Maya city. However, this thesis demonstrates that no conclusive evidence of a Mexican origin for Tezcatlipoca exists. This work rejects the near dogmatic assumption of that godas Mexican pedigree, and asserts the iconographic primacy of Tezcatlipoca imagery at the Maya city of Chichen Itza, Yucatan over the Toltec city of Tula, Hidalgo. It also suggests the possible derivation of Tezcatlipoca from the Maya God K - K'awil.

Iconographic primacy

Chichen Itza

Tula

Tezcatlipoca

God K

K'awil

Anthropology

Regulation of Syk activity in GPVI-mediated platelet activation

Thomas, Dafydd Huw

January 2010

Activation of platelets is essential for hemostasis. Following damage to the vascular endothelium collagen is exposed, to which platelets stably adhere. After adhesion on collagen, a signaling cascade is initiated, mediated by Glycoprotein VI (GPVI), which results in platelet activation. A major signaling protein in GPVI signaling is Spleen tyrosine kinase (Syk). It undergoes phosphorylation and activation following GPVI stimulation. Syk's central role in this physiological process suggests regulation of its activity is required to maintain the platelets response to collagen within physiological limits. The regulation of Syk activation is the focus of this work. Previously published reports implicate the phosphatases SHP-1, SHP-2 and TULA-2 in the negative regulation of Syk. Therefore, we tested these phosphatases possible role in platelets. We show that SHP-1 can dephosphorylate Syk in vitro, but is unable to bind Syk. Also, Syk is hypophosphorylated in GPVI-stimulated SHP-1 deficient platelets and platelet functional responses are minimally affected compared to wild-type platelets. SHP-2 is unable to bind Syk and Syk is not a good substrate for SHP-2 in vitro. TULA-2 dephosphorylated Syk in vitro and associated with Syk in platelets. In TULA-2 deficient platelets, Syk and PLCγ2 were hyperphosphorylated compared to wild-type platelets. Deletion of TULA-2 resulted in enhanced GPVI-dependent platelet functional responses and a prothrombotic phenotype. c-Cbl has been shown to be a negative regulator of GPVI signaling, possibly by regulating Syk phosphorylation. Thus, SHP-1, SHP-2 and TULA-2’s role in c-Cbl regulation of GPVI was also investigated. We show that TULA-2 is able to bind c-Cbl in platelets. SHP-1 and SHP-2 do not. Furthermore, we show a striking similarity between the phenotype of TULA-2 and c-Cbl deficient platelets. However, in vitro binding studies show TULA-2 is able to bind Syk independently of c-Cbl. Thus, the exact role of c-Cbl in regulating Syk dephosphorylation is unclear. In conclusion, we show SHP-1 and SHP-2 are probably not involved in the negative regulation of Syk. However, TULA-2 is the major phosphatase responsible for the negative regulation of Syk in GPVI signaling. This serves to negatively regulate GPVI-mediated platelet function and prevent uncontrolled platelet activation that could lead to thrombosis. / Pharmacology

Health Sciences, Pharmacology

Collagen

Gpvi

Phosphatase

Platelets

Syk

Tula

POPULATION STRUCTURE AND INTERREGIONAL INTERACTION IN PREHISPANIC MESOAMERICA: A BIODISTANCE STUDY

Aubry, Bryan Scott

03 September 2009

No description available.

Archaeology

Physical Anthropology

Dental anthropology

population genetics

R-matrix analysis

Mesoamerica

Maya

Teotihuacan

Tula

TULA-2: A Novel Protein Tyrosine Phosphatase That Regulates Osteoclast Differentiation and Function

Back, Steven

January 2014

The human skeleton is a dynamic organ that serves multiple functions to maintain normal physiology and health. It protects vital organs, provides support for movement, houses marrow and maintains calcium homeostasis. The skeleton is maintained by the work of two cells with opposing functions: osteoblasts, cells that synthesize organic bone matrix and osteoclasts that degrade and resorb it. These cells interact with one another in a tightly regulated process known as the bone remodeling cycle. This cycle maintains the health of bone by removing and replacing weak or damaged bone and responding to stress loads by remodeling portions of the skeleton that require reinforcement. Osteoblasts differentiate from mesenchymal stem cells and respond to hormonal stimuli by synthesizing and secreting cytokines necessary for osteoclast differentiation. Osteoblasts may become embedded within mineralized matrix, becoming osteocytes, cells that can sense changes in mechanical loading and facilitate localization of the remodeling cycle. Osteoclasts differentiate from hematopoietic stem cells (HSC) when the cell surface receptors, c-FMS and RANK, are activated by ligands produced by osteoblasts, M-CSF and RANKL respectively. In addition to c-FMS and RANK stimulation, another calcium-mediated, co-stimulatory pathway must be activated to ensure proper osteoclast differentiation. This pathway is activated by two immunoreceptors, OSCAR and TREM-2 that interact with adaptor proteins termed FcRγ and DAP12 respectively. These adaptor proteins harbor immunoreceptor tyrosine-based activation motifs (ITAM), which exist on their cytoplasmic tail. Once the immunoreceptors are triggered, specific tyrosines within the ITAM motifs become phosphorylated and act as docking points for the tyrosine kinase, Syk. Once bound, Syk autophosphorylates and acts on its downstream targets. Syk dephosphorylation is, therefore, necessary to attenuate this signal to prevent over activation of osteoclasts. Recently, a novel tyrosine phosphatase, T-cell Ubiquitin ligand -2 (TULA-2) has been shown to dephosphorylate specific phosphotyrosine residues on Syk in various systems and has shown an increased specificity to dephosphorylate tyrosine 352. The goal of this project is to determine how TULA-2 mediated dephosphorylation of Syk regulates osteoclast differentiation and function. TULA-2 is a member of the TULA family of proteins, TULA and TULA-2. In spite of a significant homology and similar domain organization between TULA and TULA-2, only TULA-2 has significant phosphatase activity. Furthermore, whereas TULA is expressed only in lymphocytes, TULA-2 is expressed in most tissues albeit a higher level of expression is seen in cells of hematopoietic origin. In vivo analysis including Micro-computed tomography (Micro CT) and histomorphometry indicated that mice that lack both TULA and TULA-2 (DKO) have decreased bone mass compared to wild-type (WT) counterparts. An in vitro cell differentiation assay revealed that a larger population of osteoclast-like cells (OCL) could be cultivated from bone marrow isolated from DKO mice compared to OCL derived from WT bone marrow. An in vitro resorption pit assay revealed that DKO osteoclasts could resorb bone at a faster rate than WT counterparts. Additionally, over-expression of phosphatase-dead TULA-2 in WT osteoclasts increased the ability of the cells to resorb bone. At the molecular level, activation of the co-stimulatory pathway revealed increased tyrosine phosphorylation of Syk 352 in DKO pre-osteoclasts when compared to phosphorylation of Syk isolated from WT pre-osteoclasts. Cumulatively, the above data indicates that the absence of TULA-2 results in an increased signaling response leading to a larger population of hyperactive osteoclasts, which contributes to decreased bone mass in mice. These data suggest that the phosphatase activity of TULA-2 is required for negative regulation of bone resorption. / Cell Biology

Cellular Biology

Biochemistry

Biology, Molecular

Bone Remodeling

Kinase

Osteoclast

Phosphatase

Syk

Tula-2

Dobrava and Tula hantaviruses from Central Europe

Klempa, Boris

09 February 2005

Hantaviren (Familie Bunyaviridae) sind Erreger, die von Nagetieren auf den Menschen übertragen werden und Hämorrhagische Fieber mit Renalem Syndrom (HFRS) auslösen. Die vorgelegte Arbeit beinhaltet derartige Ergebnisse zu zwei europäischen Hantaviren, dem Dobravavirus (DOBV) und dem Tulavirus (TULV). DOBV ist ein wichtiger HFRS-Erreger in Europa. DOBV Stämme kommen in mindestens zwei Nagerspecies, der Gelbhalsmaus (Apodemus flavicollis) und der Brandmaus (A. agrarius) vor. In Übereinstimmung mit diesen natürlichen Wirten bilden die Virusstämme zwei genetische Linien: DOBV-Af und DOBV-Aa. Die phylogenetischen Analysen von den Nukleotidsequenzen der S-, M- und L-Segmente von sympatrisch vorkommenden DOBV-Af und DOBV-Aa Stämmen aus Mitteleuropa zeigten das Vorkommen von Reassortmentprozessen der Genomsegmente während der Evolution der Virusspecies. Ausserdem, wurde die virale Nukleotidsequenz aus einem DOBV-seropositiven HFRS-Patienten aus Detschland amplifiziert. Damit wurde erstmalig der molekulare Beweis erbracht, dass DOBV in Mitteleuropa HFRS auslöst und dass die DOBV-Aa Linie humanpathogen ist. Aus einer in der Slowakei gefangenen A. agrarius Maus haben wir ein neues Virusisolat gewonnen, welches "Slovakia (SK/Aa)" genannt wurde. SK/Aa ist das bisher einzige Virusisolat, das die DOBV-Aa Linie repräsentiert. Es wurde gemeinsam mit einem Isolat der DOBV-Af Linie zur vergleichenden Typisierung der Antikörper von mitteleuropäischen HFRS-Patienten mittels Fokusreduktionsneutralisationstest eingesetzt. Die Seren der meisten Patienten zeigten die höchsten neutralisierenden Antikörpertiter gegenüber SK/Aa, was die Schlussfolgerung zulässt, dass DOBV-Aa Stämme für die meisten DOBV-Infektionen in Mitteleuropa verantwortlich sind. TULV wird durch die Feldmaus (Microtus arvalis) beherbergt. Die Fähigkeit zur Auslösung von HFRS war bisher wenig bekannt. Wir haben den ersten Fall von HFRS gefunden, der mit einer TULV Infektion assoziiert ist. Aus demselben geographischen Gebiet in Nordostdeutschland konnten aus Feldmäusen TULV Nukleotidsequenzen amplifiziert werden. In phylogenetischen Analysen clustern sie mit Stämmen aus Polen und bilden mit diesen gemeinsam eine eigene, neue genetische Linie. Ausser dem hier untersuchten DOBV und dem länger bekannten Puumalavirus ist TULV offenbar das dritte Hantavirus, das in Mitteleuropa HFRS hervorruft. / Hantaviruses (Bunyaviridae family) are rodent-borne bunyaviruses that cause hemorrhagic fever with renal syndrome (HFRS) in Eurasia. This thesis presents novel data about two European hantaviruses, Dobrava virus (DOBV) and Tula virus (TULV). DOBV is an important etiologic agent of HFRS in Europe. DOBV strains were found to be hosted by at least two different rodent species, yellow-necked mouse (Apodemus flavicollis) and striped field mouse (A. agrarius). According to their natural hosts they form the distinct genetic lineages DOBV-Af and DOBV-Aa, respectively. We have determined and analysed the complete S and M, and partial L segment nucleotide sequences of sympatrically occurring DOBV-Af and DOBV-Aa strains from Central Europe. Molecular phylogenetic analyses gave evidence for genetic reassortment in the evolution of the virus species. Moreover, we amplified a DOBV-Aa nucleotide sequence from a DOBV-seropositive HFRS patient from Germany. This is the first molecular identification of human infection by DOBV in Central Europe and the first direct proof that a virus strain related to the DOBV-Aa lineage, carried by A. agrarius rodents, is able to cause HFRS. Under biosafety level 3 conditions, we have established a DOBV isolate named Slovakia (SK/Aa) from an A. agrarius animal captured in Slovakia. SK/Aa, as the only isolate clearly belonging to the DOBV-Aa lineage, can be taken as the representative of this virus lineage. The new virus isolate, in comparison to a DOBV-Af strain, was used for serotyping neutralising antibodies of HFRS patients in Central Europe by the use of a focus reduction neutralisation assay. Most patients'' sera exhibited a higher end-point titer towards SK/Aa suggesting that DOBV-Aa strains are responsible for most of the DOBV HFRS cases in this region. TULV is carried by European common voles (Microtus sp.). Its pathogenic potential for humans was rather unknown. We have described the first case of HFRS which can be associated with TULV infection. Moreover, TULV strains detected in M. arvalis near the home village of the patient in North-East Germany clustered with strains from Poland and represent a new, well-supported genetic lineage within the TULV species. In addition to DOBV and longer known Puumala virus, TULV is most likely an additional causative agent of HFRS in Central Europe.

Hantavirus

Dobravavirus

Tulavirus

Nagetiere

phylogenetische Analyse

hantavirus

Dobrava virus

Tula virus

rodents

phylogenetic analysis

570 Biowissenschaften, Biologie

32 Biologie

WF 3500

XD 7304

XD 7314

ddc:570