Investigating the Relationship Between Structure, Ice Recrystallization Inhibition Activity and Cryopreservation Ability of Various Galactopyranose Derivatives

Tokarew, Jacqueline

31 May 2011

The goal of our research is to generate cryopreservation agents derived from antifreeze glycoproteins. One postulated mechanism of cell cryo-injury is ice recrystallization. It is known that simple saccharides and cryopreservation agents (DMSO) display ice recrystallization inhibition (IRI). This study assessed the cytotoxicity and cryopreservation ability of these sugars in relation to their IRI. It was determined that compounds with greater IRI have increased cytotoxicity yet confer cryoprotection. To further investigate how structure is affecting IRI activity, several galactopyranoside derivatives were synthesized. A series of deoxy and α-Callyl- deoxy galactopyranoses were prepared. Testing determined that removal of any hydroxyl group removes IRI. 3-deoxy-β-thiophenyl galactose was also synthesized and had surprisingly better IRI than β-thiophenylgalactose. Also, 6-azido galactose had similar IRI to 6-deoxy galactose. Lastly, a series of β- thioalkylgalactosides was synthesized and testing gave contradicting results which suggest that predicting IRI based on hydrophilicity is more complicated than initially hypothesized.

cryopreservation

ice recrystallization

deoxy galactosides

thiophenylgalactose

azido galactosides

amino galactosides

cytotoxicity

antifreeze glycoproteins

The Automation of Glycopeptide Discovery in High Throughput MS/MS Data

Swamy, Sajani

January 2004

Glycosylation, the addition of one or more carbohydrates molecules to a protein, is crucial for many cellular processes. Aberrant glycosylation is a key marker for various diseases such as cancer and rheumatoid arthritis. It has also recently been discovered that glycosylation is important in the ability of the Human Immunodeficiency Virus (HIV) to evade recognition by the immune system. Given the importance of glycosylation in disease, major efforts are underway in life science research to investigate the glycome, the entire glycosylation profile of an organelle, cell or tissue type. To date, little bioinformatics research has been performed in glycomics due to the complexity of glycan structures and the low throughput of carbohydrate analysis. Recent advances in mass spectrometry (MS) have greatly facilitated the analysis of the glycome. Increasingly, this technology is preferred over traditional methods of carbohydrate analysis which are often laborious and unsuitable for low abundance glycoproteins. When subject to mass spectrometry with collision-induced dissociation, glycopeptides produce characteristic MS/MS spectra that can be detected by visual inspection. However, given the high volume of data output from proteome studies today, manually searching for glycopeptides is an impractical task. In this thesis, we present a tool to automate the identification of glycopeptide spectra from MS/MS data. Further, we discuss some methodologies to automate the elucidation of the structure of the carbohydrate moiety of glycopeptides by adapting traditional MS/MS ion searching techniques employed in peptide sequence determination. MS/MS ion searching, a common technique in proteomics, aims to interpret MS/MS spectra by correlating structures from a database to the patterns represented in the spectrum. The tool was tested on high throughput proteomics data and was shown to identify 97% of all glycopeptides present in the test data. Further, the tool assigned correct carbohydrate structures to many of these glycopeptide MS/MS spectra. Applications of the tool in a proteomics environment for the analysis of glycopeptide expression in cancer tissue are also be presented.

Computer Science

Glycomics

Proteomics

Automation

Carbohydrates Structure Determination

Glycoproteins

High Throughput

Role Of Matrix Protein Of Rinderpest Virus In Viral Morphogenesis

Subhashri, R

08 1900

Rinderpest virus is an enveloped Nonsegmented Negative Stranded RNA Virus (NNSV) belonging to the genus Morbillivirus in the Family Paramyxoviridae and the causative organism for “cattle plague”. The virion has a transport component and a replication component. The transport component consists of a lipid membrane with two external membrane-anchored glycoproteins, namely Hemagglutinin (H) and Fusion (F) proteins that are necessary for cell entry and release of newly formed virus particles. The replication component consists of viral genomic RNA encapsidated by the nucleoprotein (N) and a RNA polymerase complex (Large subunit L and phosphoprotein P). These two components are linked together by the matrix protein (M) that is believed to play a crucial role in the assembly and maturation of the virion particle by bringing the two major viral components together at the budding site in the host cell. To perform this function, M protein should be able to interact with the host cellular membrane, especially the plasma membrane in the case of Rinderpest virus, should be able to interact with itself to form multimers as well as with the nucleocapsid core. The function might include the interaction of M protein with the cytoplasmic tail of the other two envelope proteins namely F and H. To understand the role of matrix protein in Rinderpest virus life cycle, the following functions were characterized – 1) Matrix protein association with the host cell membrane. 2) Matrix protein association with nucleocapsid protein. Matrix protein association cellular membranes in rinderpest virus infected cells could be a result of its interaction with the cytoplasmic tails of the viral glycoproteins. Hence, this association was characterized in the absence of other viral proteins. In transiently transfected cells, M protein existed in two isoforms namely the soluble cytosolic form and membrane-bound form. The membrane-bound M protein associated stably with the membranes, most likely by a combination of electrostatic and hydrophobic interactions, which is inhibited at high salt or high pH, but not completely. Confocal microscopy analysis showed the presence of M protein in plasma membrane protrusions. When GFP was tagged with this protein, GFP was absent from nucleus and was present predominantly in the cytosol and the plasma membrane protrusions. However, M protein expression did not result in the release of membrane vesicles (Virus-like particles) into the culture supernatant implicating the requirement of other viral proteins in envelope acquisition. Matrix protein of RPV has been shown to co-sediment with nucleocapsid during mild preparation of RNP from virus-infected cells. This association was further investigated by virus solubilization. The matrix protein could be solubilised completely from virion only in the presence of detergent and high salt. This is in agreement with the previous observation from the laboratory that the purified matrix protein remained soluble in the presence of detergent and 1M NaCl. This suggested that M protein could oligomerise or associate with nucleocapsid. The purified M protein when visualized by Electron microscopy showed the presence of globular structures, which may be due to self association of M protein, which may be due to self-aggregation of M protein. The presence of GFPM in filamentous structures in transfected cells, as visualized by confocal microscopy could also be due to self-assembly of M protein. Interaction of matrix protein RPV nucleocapsid was confirmed using co- sedimentation and floatation gradient analysis. Results obtained from M-N binding assay using C-terminal deletions of nucleocapsid protein suggested that the matrix protein interacted with the conserved N-terminal core of nucleocapsid and non- conserved C-terminus 20% is dispensable. This is in agreement with the report that RPV M protein could be replaced with that of Peste-des-petits-ruminants virus(a closely related morbillivirus). The observation that the nucleocapsid protein interacts with both soluble and membrane-bound form suggests that the matrix protein can possibly interact itself to facilitate the assembly of replication component at the site of budding where the transport component is already assembled. Viral proteins of many RNA viruses interact with detergent-resistant host components that facilitate their transport inside the cell to the sits of assembly or replication. Rinderpest viral proteins acquire detergent resistance in infected cells. This acquisition is mediated by viral N protein. The relevance of this interaction in virus life cycle was studied using small molecule drugs that disrupt host cytoskeleton and lipid raft. The results obtained suggested that the host cytoskeleton, especially actin-filaments facilitate virus release from the plasma membrane. RPV matrix protein acquired detergent resistance in infected cells as well as in transfected cells. The pattern of detergent resistance suggested an association with the cytoskeleton or cytoskeleton associated proteins. However, results obtained from co-localisation studies in the presence of actin inhibitor and cold-ionic detergents are not consistent with the above observation. This property could be due to self-association of matrix protein.

Glycoproteins

Lipid Membranes

Viral Morphogenesis

Rinderpest Virus

Virus Solubilization

Viral Proteins

Cattle Plague

Matrix Protein

Microbiology

Untersuchungen zur Rolle der O-glykosidisch gebundenen N-Acetylglucosamin-Modifikation von Proteinen beim proteolytischen Prozessieren des humanen Amyloid Precursor Proteins

Mäss, Carmen.

January 2002

Disputats. Rheinische Friedrick-Wilhelms-Universität, 2002. / Haves kun i elektronisk udg.

The role of perforin and chemokines in the pathogenesis of chronic corneal inflammation induced by herpes simplex virus type-1 infection /

Chang, Eddie,

January 2003

Thesis (Ph. D.)--University of Missouri--Columbia, 2003. / "May 2003." Typescript. Vita. Includes bibliographical references (leaves 139-154).

Pregnancy-associated glycoprotein (PAG) profiles in cows and goats and attempts to measure PAG in milk

Shahin, Mazhar

07 November 2012

No description available.

630

PAG

breeds

goats

cows

pregnancy

glycoproteins

Cattle

Aubrac

holstein

Land- und Forstwirtschaft (PPN621302791)

Treatment of nonspecific DNA-protein contacts and application to the excision mechanism of a unique human DNA glycosylase

Rutledge, Lesley R, University of Lethbridge. Faculty of Arts and Science

January 2011

This thesis concentrates on understanding how individual nonspecific DNA–protein contacts are used in the excision mechanism of the human DNA repair enzyme, alkyladenine DNA glycosylase (AAG). Initially, studies focus on understanding the structure and magnitude of these fundamentally different DNA–protein stacking and T-shaped interactions to be applied to the active site of AAG. High-level ab initio techniques revealed fundamental knowledge about the structure and magnitude of these distinctly different – and +– contacts between (one or two) conjugated amino acid(s) and one nucleobase. Additionally, the mechanism used by AAG to excise (neutral and cationic) damaged nucleotides was investigated using a hybrid ONIOM approach. Reaction potential energy surfaces reveal that AAG prefers to excise both neutral and cationic substrates through a concerted mechanism, yet the nonspecific contacts present in the active site are only catalytic for the cleavage of the neutral substrates. / xvi, 195 leaves : ill. (some col.) ; 29 cm + 1 CD-ROM

DNA ligases -- Research

DNA repair -- Research

DNA -- Methylation -- Research

Alkylation

Glycoproteins -- Research

Dissertations, Academic

Investigating the Relationship Between Structure, Ice Recrystallization Inhibition Activity and Cryopreservation Ability of Various Galactopyranose Derivatives

Tokarew, Jacqueline

31 May 2011

The goal of our research is to generate cryopreservation agents derived from antifreeze glycoproteins. One postulated mechanism of cell cryo-injury is ice recrystallization. It is known that simple saccharides and cryopreservation agents (DMSO) display ice recrystallization inhibition (IRI). This study assessed the cytotoxicity and cryopreservation ability of these sugars in relation to their IRI. It was determined that compounds with greater IRI have increased cytotoxicity yet confer cryoprotection. To further investigate how structure is affecting IRI activity, several galactopyranoside derivatives were synthesized. A series of deoxy and α-Callyl- deoxy galactopyranoses were prepared. Testing determined that removal of any hydroxyl group removes IRI. 3-deoxy-β-thiophenyl galactose was also synthesized and had surprisingly better IRI than β-thiophenylgalactose. Also, 6-azido galactose had similar IRI to 6-deoxy galactose. Lastly, a series of β- thioalkylgalactosides was synthesized and testing gave contradicting results which suggest that predicting IRI based on hydrophilicity is more complicated than initially hypothesized.

cryopreservation

ice recrystallization

deoxy galactosides

thiophenylgalactose

azido galactosides

amino galactosides

cytotoxicity

antifreeze glycoproteins

The Rational Design of Potent Ice Recrystallization Inhibitors for Use as Novel Cryoprotectants

Capicciotti, Chantelle

07 February 2014

The development of effective methods to cryopreserve precious cell types has had tremendous impact on regenerative and transfusion medicine. Hematopoietic stem cell (HSC) transplants from cryopreserved umbilical cord blood (UCB) have been used for regenerative medicine therapies to treat conditions including hematological cancers and immodeficiencies. Red blood cell (RBC) cryopreservation in blood banks extends RBC storage time from 42 days (for hypothermic storage) to 10 years and can overcome shortages in blood supplies from the high demand of RBC transfusions. Currently, the most commonly utilized cryoprotectants are 10% dimethyl sulfoxide (DMSO) for UCB and 40% glycerol for RBCs. DMSO is significantly toxic both to cells and patients upon its infusion. Glycerol must be removed to <1% post-thaw using complicated, time consuming and expensive deglycerolization procedures prior to transfusion to prevent intravascular hemolysis. Thus, there is an urgent need for improvements in cryopreservation processes to reduce/eliminate the use of DMSO and glycerol. Ice recrystallization during cryopreservation is a significant contributor to cellular injury and reduced cell viability. Compounds capable of inhibiting this process are thus highly desirable as novel cryoprotectants to mitigate this damage. The first compounds discovered that were ice recrystallization inhibitors were the biological antifreezes (BAs), consisting of antifreeze proteins and glycoproteins (AFPs and AFGPs). As such, BAs have been explored as potential cryoprotectants, however this has been met with limited success. The thermal hysteresis (TH)activity and ice binding capabilities associated with these compounds can facilitate cellular damage, especially at the temperatures associated with cryopreservation. Consequently, compounds that possess “custom-tailored” antifreeze activity, meaning they exhibit the potent ice recrystallization inhibition (IRI) activity without the ability to bind to ice or exhibit TH activity,are highly desirable for potential use in cryopreservation. This thesis focuses on the rational design of potent ice recrystallization inhibitors and on elucidating important key structural motifs that are essential for potent IRI activity. While particular emphasis in on the development of small molecule IRIs, exploration into structural features that influence the IRI of natural and synthetic BAs and BA analogues is also described as these are some of the most potent inhibitors known to date. Furthermore, this thesis also investigates the use of small molecule IRIs for the cryopreservation of various different cell types to ascertain their potential as novel cryoprotectants to improve upon current cryopreservation protocols, in particular those used for the long-term storage of blood and blood products. Through structure-function studies the influence of (glyco)peptide length, glycosylation and solution structure for the IRI activity of synthetic AFGPs and their analogues is described. This thesis also explores the relationship between IRI, TH and cryopreservation ability of natural AFGPs, AFPs and mutants of AFPs. While these results further demonstrated that BAs are ineffective as cryoprotectants, it revealed the potential influence of ice crystal shape and growth progression on cell survival during cryopreservation. One of the most significant results of this thesis is the discovery of alkyl- and phenolicglycosides as the first small molecule ice recrystallization inhibitors. Prior to this discovery, all reported small molecules exhibited only a weak to moderate ability to inhibit ice recrystallization. To understand how these novel small molecules inhibit this process, structure-function studies were conducted on highly IRI active molecules. These results indicated that key structural features, including the configuration of carbons bearing hydroxyl groups and the configuration of the anomeric center bearing the aglycone, are crucial for potent activity. Furthermore, studies on the phenolic-glycosides determined that the presence of specific substituents and their position on the aryl ring could result in potent activity. Moreover, these studies underscored the sensitivity of IRI activity to structural modifications as simply altering a single atom or functional group on this substituent could be detrimental for activity. Finally, various IRI active small molecules were explored for their cryopreservation potential with different cell types including a human liver cell line (HepG2), HSCs obtained from human UCB, and RBCs obtained from human peripheral blood. A number of phenolic-glycosides were found to be effective cryo-additives for RBC freezing with significantly reduced glycerol concentrations (less than 15%). This is highly significant as it could drastically decrease the deglycerolization processing times that are required when RBCs are cryopreserved with 40% glycerol. Furthermore, it demonstrates the potential for IRI active small molecules as novel cryoprotectants that can improve upon current cryopreservation protocols that are limited in terms of the commonly used cryoprotectants, DMSO and glycerol.

Cryopreservation

Ice Recrystallization Inhibition

Carbohydrates

Antifreeze Glycoproteins

Antifreeze Proteins

Red Blood Cells

Hematopoietic Stem Cells

Cryoprotectants

BALTYMŲ FRAKCIJŲ, PRATURTINTŲ LEKTINAIS, IŠSKIRTŲ IŠ URTICA DIOICA L. ŽOLĖS IR SAUSOJO EKSTRAKTO, KOKYBINĖ – KIEKYBINĖ ANALIZĖ IR MIKROBIOLOGINIS TYRIMAS / QUALITATIVE – QUANTITATIVE ANALYSIS AND ANTIBACTERIAL ACTIVITY EVALUATION IN LECTIN ENRICHED PROTEIN FRACTIONS FROM HERB AND DRY EXTRACT OF URTICA DIOICA L

Balčiūnaitė, Gabrielė

18 June 2014

Darbo tikslas: Kokybinė - kiekybinė baltymų frakcijų, praturtintų lektinais, iš Urtica dioica L. žolės, sausojo ekstrakto analizė ir antimikrobinio poveikio įvertinimas. Darbo uždaviniai: 1. Išskirti baltymų frakcijas, praturtintas lektinais, iš Urtica dioica L. šviežios ir džiovintos žolės bei sausojo ekstrakto; 2. Sausos Urtica dioica L. žolės frakcijose nustatyti baltymų dalelių dydį; 3. Įvertinti baltymų frakcijų, išskirtų iš Urtica dioica L. šviežios ir džiovintos žolės bei sausojo ekstrakto, hemagliutinacinį aktyvumą; 4. Kiekybiškai įvertinti baltymų kiekį gautose frakcijose; 5. Atlikti kiekybinę lektinų analizę pagal hemagliutinacijos titrą; 6. Įvertinti lektinais praturtintų frakcijų, išskirtų iš Urtica dioica L. džiovintos žolės bei sausojo ekstrakto, antimikrobinį aktyvumą. Darbo metodai: 1. Lektinais praturtintas baltymų frakcijas išskyrėme, taikydami tirpalų prisotinimą amonio sulfatu iki skirtingos procentinės koncentracijos; 2. Lektinai identifikuoti, pritaikius triušio eritrocitų hemagliutinacijos reakciją; 3. SDS – PAGE elektroforezės metodu nustatytas frakcijų dalelių dydis; 4. Bradfordo metodu kiekybiškai įvertinta baltymų sudėtis išskirtose frakcijose; 5. Lektinai kiekybiškai įvertinti pagal hemagliutinacinį aktyvumą; 6. Antibakterinis aktyvumas įvertintas standžiosiose Miulerio – Chintono agaro mitybos terpėse cilindriukų metodu. Tyrimo rezultatai: 1. Hemagliutinacinis aktyvumas nustatytas visose išskirtose baltymų frakcijose. 2. Didžiausiu... [toliau žr. visą tekstą] / Aim of experiment: The qualitative – quantitaive analysis and antibacterial activity evaluation of lectin enriched protein fractions from Urtica dioica L. fresh and dry herb and dry extract; Experiment tasks: 1. To extract the lectin enriched protein fractions from Urtica dioica L. fresh and dry herb and dry extract; 2. To assess the size of protein particles from Urtica dioica L. dry herb by SDS-PAGE assay; 3. To determine the hemagglutinating activity of lectin enriched fractions from Urtica dioica L. fresh and dry herb and dry extract; 4. To evaluate the protein amount in prepared fractions by Bradford assay; 5. To analyse the lectin amount by hemagglutination titre; 6. To evaluate the antibacterial activity of lectin enriched fractions from Urtica dioica L. fresh and dry herb and dry extract; Methods: 1. We used the precipitation with ammonium sulphate for the extraction of lectin enriched protein fractions; 2. Lectins were identified by hemagglutination assay; 3. We determined the size of protein particles using SDS-PAGE method. 4. We evaluated protein amount in fractions by Bradford assay; 5. Lectin quantity was evaluated by hemagglutination titer; 6. We evaluated the antibacterial activity on solid medium with Peni cylinders. Results: 1. The hemagglutinating activity was found in all protein fractions. 2. Maximum of hemagglutinating activity (2,95) was noticed in the first lectin enriched protein fraction from fresh Urtica dioica L. herb. 3. The particle size was... [to full text]

Pharmacy

Augalų lektinai

Hemagliutinacija

Urtica dioica L

Glikoproteinai

Plant lectin

Hemagglutination

Urtica dioica L

Glycoproteins