En studie om gropkeramikernas förhållningssätt kring kollaps och resiliens, med den adaptiva modellen som analysmetod / A study of the pitted ware culture and their approach towards collapse andresilience, using the adaptive cycle as a method of analysis

Lind, Victoria

January 2023

Gropkeramiker är en intressant kultur som utmärker sig under mellanneolitisk tid på grund av de mesolitiska jakttendenserna. Denna text undersöker gropkeramikernas förhållningssätt kring motgångar och resiliens, genom att registrera potentiella motgångar inom kulturen. Detta kommer att genomföras genom att sammanställa källor från tidigare forskning kring kulturen samt utgå från den adaptiva modellen där kollaps och resiliens definieras. De sammanställda källorna inkluderar gropkeramikernas kontaktnät, ritualer, diet, osteologiska analyser, DNA - analyser och handel. Uppsatsen har avgränsat det geografiska området där de primära källorna inkluderar lokalerna: Ajvide, Västerbjers och Jettböle. / Pitted ware culture is an interesting culture during the middle neolithic period due to the mesollithic hunting tendencies. This text examines the cultures approach to setbacks and resilience by registering potential setbacks within the culture. This will be done by compiling sources from previous research on pitted ware culutre and by using the adaptive model where collapse and resilience are defined. The compiled sources include the social network, rituals, diet, osteological analyses, DNA - analysis and trade of the pitted ware culture. This essay has defined the geographical area where the primary sources include the sites of: Ajvide, Västerbjers and Jettböle.

Resilience

collapse

disturbances

Pitted ware culture

Battle Axe

Ajvide

Västerbjers

Jettböle

Resiliens

kollaps

GRK

SYK

Ajvide

Västerbjers

Jettböle

History and Archaeology

Historia och arkeologi

The Petz (lite) recovery map for scrambling channel / スクランブリングなチャンネルに対するペッツ(ライト)復元写像

Nakayama, Yasuaki

25 March 2024

京都大学 / 新制・課程博士 / 博士(理学) / 甲第25109号 / 理博第5016号 / 新制||理||1715(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 橋本 幸士, 教授 杉本 茂樹, 教授 田島 治 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM

Black hole information loss problem

Hayden-Preskill decoding protocol

Petz recovery map

SYK model

Quantum chaos

Replica wormhole

Quantum Error Correction

400

INHIBITION OF ERYTHROCYTE BAND 3 TYROSINE PHOSPHORYLATION: CHARACTERIZATION OF A NOVEL THERAPY FOR SICKLE CELL DISEASE AND MALARIA

Panae Noomuna (10716546)

29 April 2021

While the molecular defect that cause sickle cell disease has well been established, the cause of vaso-occlusive crisis remains elusive and largely debated upon. Majority of studies have linked the painful episodes to polymerization of sickle hemoglobin following its deoxygenation. The variability of the disease symptoms among patients, compounds efforts for a holistic therapy. Hydroxyurea, a stimulator of Hb F induction and a widely used treatment, has ameliorated the complication of SCD but it is only effective in 50% of the patients. Expression of Hb F lowers the content of Hb S in blood and hence reduces oxidative stress caused by Hb S denaturation. Sickle cell disease severity depends on several factors. Most importantly, the ability of red cell to sickle dominates all other determinants. While deoxygenation of sickle hemoglobin may be inevitable, the duration with which the red cell remains in the deoxygenated state can be manipulated. Deoxygenation is a transient process that when compared to the time taken to develop the long filaments of deoxyhemoglobin to causes severe sickling, the red cell would have been cycled back to the lungs and re-oxygenated to restore the healthy conditions of the cell. In fact, if sickle cells would flow as fast as healthy erythrocytes, the detrimental impacts of sickling such as vaso-occlusive crisis, would not be a concern for this disease. Unfortunately, the unstable sickle hemoglobin undergoes denaturation through auto-oxidation, which imposes oxidative stress to the cells. The oxidative stress inhibits erythrocytes tyrosine phosphatases, a course which subsequently impair their constitutive action against the tyrosine kinases. In the end, a net tyrosine phosphorylation state in the red cell membrane proteins, most notably the transmembrane protein band 3, succeeds. Band 3 tyrosine phosphorylation abrogates the protein’s interaction with ankyrin and spectrin-actin cytoskeleton, hence the cytoskeleton loses its major anchorage to the membrane thus engendering membrane destabilization. A destabilized erythrocyte sheds membrane fragments in form of microvesicles/microparticles and discharges free hemoglobin into the extra cellular matrix. In consequence, the microparticles power initiation of coagulation cascade through activation of thrombin, while free Hb inflicts inflammation, scavenges nitric oxide which is necessary for vasodilation and induces further oxidative stress within the microvasculature, and activates expression of adhesion receptors on the endothelium. Taken together, these events culminate in entrapment of red cells (not naming leucocytes and platelets) in the microvasculature, blockade of blood vessels and further damage of erythrocytes through prolonged deoxygenated state thus terminating in tissue injury, strokes, and organ damage, amid vaso-occlusive episodes which always require hospitalization and extensive medical care for survival. Band 3 tyrosine phosphorylation and membrane weakening is not unique just to SCD, but also a druggable target for malaria. Malaria, a disease that is touted as the evolutionary cause of sickle cell disease, surprisingly thrives through the same mechanism. Briefly, malaria parasite consumes hemoglobin for its DNA synthesis, and in the process generate reactive oxygen species from denatured hemoglobin that feeds into the oxidative stress which triggers band 3 tyrosine phosphorylation. In this case however, a destabilized membrane offers perfect conditions for merozoites’ (malaria daughter parasites) egress/exit out of the cell to begin infecting other red cells. Ultimately, the ensuing anemia and organ dysfunction leads to patient’s death. Treatment of diseased cells with imatinib and other Syk inhibitors effectively reversed membrane weakening. A stabilized membrane not only survives longer in circulation to alleviate SCD symptoms but also traps and starves malaria parasite leading to termination of the parasitic infection. With band 3 tyrosine phosphorylation at center stage, this dissertation explores the above events in an effort to unveil a novel therapy for sickle cell and malaria diseases. First, the therapeutic strategy regarding SCD is discussed in detail beginning with non-transfused patients and ending in additional mechanistic study on inactivation of the principal erythrocyte’s protein tyrosine phosphatase 1 B, PTP1B. The dissertation then provides an initial proof of concept on efficacy of imatinib in treatment of malaria as a monotherapy and its efficacy when used in a triple combination therapy with the standard of care treatment. Finally, I outline an alternative possible mechanism of action of quinine against malaria.

Biochemistry

Molecular Medicine

Proteins and Peptides

band 3 phosphorylation

Sickle Cell Disease Candidate drugs

PTP1B activity

Syk inhibitors

quinine alkaloids

mechanism of action of quinine

PTP1B cleavage in sickle cell

band 3 tyrosine phosphorylation

sickle cell disease treatment

Modulace funkce plazmacytoidních dendritických buněk: role immunoreceptorů TIM-3 a BDCA-2 / Modulation of plasmacytoid dendritic cell function: role of immunoreceptors TIM-3 and BDCA-2

Font Haro, Albert

January 2021

Albert Font Haro ABSTRACT Modulation of plasmacytoid dendritic cell function: role of immunoreceptors TIM-3 and BDCA-2 Plasmacytoid dendritic cells (pDCs) are key players in the antiviral response as well as in linking innate and adaptive immune response. They express endosomal toll-like receptors 7 and 9, which can detect ssRNA and unmethylated CpG DNA, respectively. Due to the constitutive expression of the transcription factor IRF7, pDCs are able to rapidly produce massive quantities of type I (α, β, ω) and type III (1, 2, 3, 4) interferons (IFN-I and IFN-III) as well as pro- inflammatory cytokines such as IL-1, IL-6 and TNF-α. After maturation, they also function as antigen-presenting cells. Despite intense research, the mechanisms of IFN and pro-inflammatory cytokines production and regulation are still poorly understood. Using the pDC cell line GEN2.2 and also primary human pDCs, we shed light on the role of kinases MEK and SYK in IFN-I production and regulation. We found that SYK is not only involved in the regulatory receptor (RR)-mediated BCR-like pathway that represents the negative regulation of IFN-I and IFN-III secretion but also in the positive TLR7/9-mediated signal transduction pathway that leads to IFN-I production, representing the immunogenic function. We also found that MEK plays a...