<i>Schizosaccharomyces pombe </i> Phosphatidylinositol 4-kinase, Pik1p, in cell cycle control

Park, Jae-Sook

15 May 2007

Pik1p, one of three phosphatidylinositol 4-kinases in the fission yeast, <i>Schizosaccharomyces pombe</i>, was found previously to interact with Cdc4p, a myosin essential light chain that is required for cytokinesis. The involvement of pik1 in cell cycle control was investigated. A fluorescently tagged Pik1p fusion protein was associated with Golgi throughout the cycle, and was found at the medial division plane of the cell during late cytokinesis. This latter distribution has not been reported previously. Gene deletion in diploid cells and tetrad analysis revealed that pik1 is essential for cell viability and is required for spore germination. The terminal phenotype of a temperature-sensitive, loss-of-function allele (pik1-td) indicated that pik1 is involved in cytokinesis: particularly for suppression of secondary septum material deposition, for suppression of initiation of supernumerary septa, and for cell separation. Contractile ring formation was normal in pik1-td cells at the restrictive temperature although the pattern of F-actin patches was disrupted. The F-actin patches were dispersed throughout the cytoplasm. Accumulation of extra inner membranous or vesicle-like structures was observed in these cells. The <i>S. pombe</i> nmt1 promoter and attenuated versions of it were found to be useful for complementation studies in <i>S. cerevisiae</i>. Heterologous expression of <i>S. pombe</i> pik1 complemented the essential functions of a temperature-sensitive allele (pik1﷓101) of its orthologue in <i>Saccharomyces cerevisiae</i> that were lost at the restrictive temperature. A residue required for <i>S. pombe</i> Pik1p lipid kinase activity, D709, was also required for this complementation. A residue, R838, which is required for interactions between Pik1p and Cdc4p was not required for this complementation. The timing and localization of Pik1p to the division plane of the cell late in cytokinesis combined with analysis of the terminal phenotype of a loss-of-function allele, indicate that Pik1p and/or its derived phosphoinositides are required for regulation of septation and cell separation. Pik1p may be involved in the transport, possibly via vesicular transport, of enzymes required for hydrolysis of the primary septum. It may be involved in signaling pathways that lead to the initiation of septation and to the cessation of the deposition of secondary septum material.

lipid kinases

cell separation

septation

cytokinesis

lipid phosphatases

Membrane-Disrupting Activity of Antimicrobial Peptides and the Electrostatic Bending of Membranes

Taheri-Araghi, Sattar

January 2010

Antimicrobial peptides (AMPs) are not only fast microbe-killing molecules deployed in the host defense of living organisms but also offer valuable lessons for developing new therapeutic agents. While the mode of action of AMPs is not clearly understood yet, membrane perturbation has been recognized as a crucial step in the microbial killing mechanism of many AMPs. In this thesis, we first present a physical basis for the selective membrane-disrupting activity of cationic AMPs. To this end, we present a coarse-grained physical model that approximately captures essential molecular details such as peptide amphiphilicity and lipid composition (e.g., anionic lipids). In particular, we calculate the surface coverage of peptides embedded in the lipid headgroup-tail interface and the resulting membrane-area change, in terms of peptide and membrane parameters for varying salt concentrations. We show that the threshold peptide coverage on the membrane surface required for disruption can easily be reached for microbes, but not for the host cell -- large peptide charge (≳4) is shown to be the key ingredient for the optimal activity-selectivity of AMPs (in an ambient-salt dependent way). Intriguingly, we find that in a higher-salt environment, larger charge is required for optimal activity. Inspired by membrane softening by AMPs, we also study electrostatic modification of lipid headgroups and its effects on membrane curvature. Despite its relevance, a full theoretical description of membrane electrostatics is still lacking -- in the past, membrane bending has often been considered under a few assumptions about how bending modifies lipid arrangements and surface charges. Here, we present a unified theoretical approach to spontaneous membrane curvature, C₀, in which lipid properties (e.g., packing shape) and electrostatic effects are self-consistently integrated. Our results show that C₀ is sensitive to the way lipid rearrangements and divalent counterions are modeled. Interestingly, it can change its sign in the presence of divalent counterions, thus stabilizing reverse hexagonal (H_II) phases.

Antimicrobial peptides

Lipid bilayer

Bending of lipid membranes

Physics

Lipids and follicular function

Hamilton, Richard Phillip

January 1979

vii, 203 leaves : tables, graphs ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.1980) from the Dept. of Obstetrics and Gynaecology, University of Adelaide

Graafian follicle Analysis.

Gonodotropin Physiological effect.

Lipid metabolism.

Lipid synthesis.

Developing a Cell-like Substrate to Investigate the Mechanosensitivity of Cell-to-Cell Junctions

Shilts, Kent D.

08 1900

Indiana University-Purdue University Indianapolis (IUPUI) / The role of mechanical forces in the fate and function of adherent cells has been revealed to be a pivotal factor in understanding cell biology. Cells require certain physical cues to be present in their microenvironment or the cell will begin apoptosis. Mechanical signals from the environment are interpreted at the cellular level and biochemical responses are made due to the information from outside the cell, this process is known as mechanotransduction. Misinterpretation of physical cues has been indicated in many disease states, including heart disease and asthma. When a cell is bound to the ECM, proteins such as integrins are engaged at static and stable adhesion sites. These tight and static anchoring points found at the ECM exist in stark contrast to the dynamic conditions seen at intercellular junctions. Intercellular junctions, such as gap and adherens junctions, are formed between cells to act as a mechanism to relay information and exchange material. Due to the important role intercellular junctions play in processes of wound healing, epithelial-mesenchymal transition and cancer metastasis developing more sophisticated levels of understanding of these mechanisms would provide valuable insight. Complex biological processes, including immune cell signaling and cellular ECM adhesions, have been effectively replicated in model systems. These model systems have included the use of solid supported lipid bilayers and polymeric hydrogels that display cell adhesion molecules. Studies of cellular mechanotransduction at ECM adhesion sites has also been completed with covalently functionalized polymeric substrates of adjustable elasticity. However, developing model systems that allow the accurate reproduction of properties seen at intercellular junctions, while also allowing the investigation of cellular mechanosensitivity has proven to be a difficult task. Previous work has shown that polymer-tethered lipid bilayers (PTLBs) are a viable material to allow the replication of the dynamics and adhesion seen at intercellular junctions. Although efforts have been made to produce PTLBs with different mechanical properties, there is currently not a material with sufficient tunable elastic properties for the study of cellular mechanotransduction. To establish a system that allows the study of stiffness effects across a biologically relevant range (~0.50 – 40 kPa) while maintaining the dynamic properties seen at cell-to-cell junctions, polymer gel-tethered bilayers (PGTBs) were developed. A fabrication strategy was established to allow the incorporation of a hydrogel support with easily tunable stiffness and a tethered lipid bilayer coating, which produced a powerful platform to study the effects of stiffness at intercellular junctions. Careful attention was given to maintain the beneficial properties of membrane diffusion, and it was shown that on different linking architectures lipid bilayers could be established and diffusion was preserved. Microscopy-based FCS and FRAP methodology were utilized to measure lipid diffusion in these systems, while confocal microscopy was used to analyze cell spreading and adhesion. Three distinct architectures to link the lipid membrane to the underlying polyacrylamide hydrogel were pursued in this work, a non-covalent biotin-streptavidin system, a covalently linked design with fibronectin, and a direct covalent linkage utilizing crosslinker chemistry. In this work, it was shown that cells were able to spread and adhere on these substrates, with cell adhesion zones visualized under plated cells that demonstrate the capability of the cell to rearrange the presented linkers, while maintaining a stable material. Also confirmed is the tunability of the polymer hydrogel across a wide range of stiffness, this was shown by quantitative changes in cell spreading area in response to polymer properties.

Lipid membrane

Artificial lipid bilayer

Cellular mechanosensitivity

Cell substrate

Impact of pathogenic SMS2 variants on lipid landscapes and membrane properties along the secretory pathway

Sokoya, Tolulope Tolu Victor

28 June 2022

Sphingomyelin (SM) is a major component of mammalian cell membranes. Its bulk production in the trans-Golgi provides a thermodynamic trap for cholesterol synthesized in the ER to promote the formation of a SM/sterol concentration gradient along the secretory pathway. This gradient marks a fundamental transition in physical membrane properties that helps specify organelle identity and function. A previous study identified mutations in SM synthase SMS2 as the underlying cause of a hereditary form of osteoporosis and skeletal dysplasia. This work shows that two missense SMS2 variants linked to the most severe bone phenotype, p.I62S and p.M64R, retain full enzymatic activity but are unable to leave the ER owing to a defective autonomous ER export signal. Consequently, bulk production of SM is mistargeted to the ER, the site for de novo synthesis of the SM precursor ceramide. Combining organellar lipidomics with the application of lipid reporters, I find that cells harboring these pathogenic SMS2 variants accumulate plasma membrane-like SM levels in the ER and display a disrupted SM asymmetry at the plasma membrane, presumably due to a constitutive SM scrambling in the ER. These aberrant SM distributions also occur in patient-derived fibroblasts and are accompanied by significant imbalances in cholesterol organization and lipid order along the secretory pathway. Moreover, I find that a more common nonsense SMS2 variant associated with a milder bone phenotype, p.R50X, yields a truncated but catalytically active enzyme that is mistargeted to an early Golgi compartment. Collectively, these data indicate that pathogenic SMS2 variants undermine the capacity of cells to uphold nonrandom lipid distributions in the secretory pathway that may be critical for the bone forming activity of osteogenic cells.

Cell Biology

Lipid biology

Sphingomyelin

Cholesterol

Lipid reporters

ddc:570

Effects of a Comprehensive Wellness Program on Serum Lipid Concentration Among the Residents

Williams, Kimberly A.

16 December 2010

No description available.

Nutrition

cholesterol

FIT FOR LIFE

LDL

HDL

LIPID

blood lipid

The environmental biogeochemistry of open ocean and partially enclosed marine systems

Dias, Isobelle A.

January 1990

No description available.

551.9

Lipid biomarkers in the N. Sea

Ethanol consumption and adipose tissue lipase activity in CBA mice

Shih, Mei-Fen

January 1996

No description available.

572

Obesity; Diabetes; Lipid mobilisation

Plasma membrane sterols and fatty acids : effects on membrane properties and H'+-ATPase of Ustilago maydis

Hernandez Lopez, Agustin

January 1996

No description available.

572

Protein-lipid interaction; Fungicides

Amylose-lipid relationships in starch of maturing wheat grain

Gadan, H. M.

January 1984

No description available.

572

Amylose-lipid in grain starch