Analysis of Sp1 associated transcription regulatory factors bound on TSG101 promoter by DAPA and two dimensional gel electrophoresis

LIN, I-Ju

25 August 2008

TSG101 is a tumor susceptibility gene exhibits multiple biological functions, including the regulation of vesicular trafficking, transcription, cellular growth and differentiation. The intracellular steady-state level of TSG101 was shown to under stringent control in a narrow range. Either deprivation or overexpression of mouse tsg101 in NIH3T3 cells leads to neoplastic transformation and subsequent tumorigenic potential of the transformed cells. However, the detail mechanism for regulation of TSG101 gene promoter activity is not clear. Our results indicated TSG101 is a housekeeping gene and contains a TATA-less and Sp1 binding site promoter. Here, we demonstrate in vivo binding of Sp1 transcription factor on TSG101 promoter region by chromatin immunoprecipitation(ChIP). In addition, Sp1-associated transcription regulators were purified using DNA affinity precipitation assay (DAPA) method and subjected to two-dimensional gel electrophoresis and the subsequent MALDI-TOF analysis. Our results verify the biding of Sp1 transcription on the DAPA probe containing wildtype but not the mutant Sp1 biding sequence by subsequent western blotting. Our MALDI-TOF analysis of protein spots from two-dimensional gel did not reveal the binding of Sp1 protein, instead the identified a number of cellular proteins, such as U5 small nuclear RNP¡BATP-dependent DNA helicase 2 and actin of unknown significance.

Sp1

TSG101

two dimensional gel electrophoresis

Proteomic Analysis Of Listeria Monocytogenes

Mujahid, Sana

15 December 2007

Listeria monocytogenes is a deadly, Gram-positive foodborne pathogen that is ubiquitous in the environment. The bacterium expresses a number of virulence and stress adaptation proteins that support its pathogenic capabilities. Two-dimensional gel electrophoresis (2-DE) was used to map L. monocytogenes surface proteins, which play a central role in virulence, and to examine protein expression by L. monocytogenes grown on ready-to-eat meat, an important source of Listeria infections. A novel method for solubilization of surface proteins from L. monocytogenes for 2-DE was developed. Additionally, the unique proteome expressed by L. monocytogenes grown on a meat matrix was uncovered. The developed solubilization method will facilitate efforts to identify and routinely compare surface proteins of Listeria by 2-DE. Furthermore, the 2-DE database of proteins expressed by L. monocytogenes grown on a meat matrix will allow further understanding of the interactions of Listeria with its food environment that influence its ability to cause disease.

two-dimensional gel electrophoresis

proteomics

Listeria monocytogenes

Molecular and physiological responses of <i>salmonella enterica serovar</i> enteritidis ATCC 4931 to <i>trisodium phosphate</i>

Sampathkumar, Balamurugan

08 September 2003

Salmonella species continue to be commonly associated with cases of food-borne disease in developed countries. In the United States in 2001, the incidence per 100,000 people was highest for salmonellosis (15.1), followed by campylobacteriosis (13.8) and shigellosis (6.4). Enteric pathogens usually contaminate the surface of raw animal products during slaughter and primary processing (scalding, defeathering or dehiding, rinsing, cutting, mixing, and grinding, etc.) and can attach and/or reside in the regular and irregular surfaces of the skin, multiply and, thereafter, contaminate food preparation surfaces, hands and utensils. Trisodium phosphate (TSP) has been approved by the USDA as a sanitizer to reduce surface loads of Salmonella on chicken carcasses. A number of studies had demonstrated that TSP effectively removes surface contamination of carcasses by food-borne pathogens. However, very little scientific evidence is available which identifies the actual mechanisms of TSP antimicrobial activity and the response of food-borne pathogens exposed to TSP. This study examined both the physiological and molecular response of Salmonella enterica serovar Enteritidis to TSP treatment. The role of high pH during TSP treatment on its antimicrobial activity was examined. Adaptation of S. enterica serovar Enteritidis to TSP treatment was also examined by analyzing the proteome of serovar Enteritidis cells using two-dimensional gel electrophoresis and mass spectrometry. The role of high pH on the antimicrobial activity of TSP was examined using comparative studies involving treatment solutions containing different concentrations of TSP, treatment solutions adjusted to the equivalent pH as in each of the TSP treatments and TSP solutions pH adjusted to 7.0. Direct and indirect indices of cell survival, membrane damage, and cellular leakage were also employed to examine specific antimicrobial effects. Cell viability, loss of membrane integrity, cellular leakage, release of lipopolysaccharides and cell morphology were accordingly examined and quantified under the above treatment conditions. Exposure of serovar Enteritidis cells to TSP or equivalent alkaline pH made with NaOH resulted in the loss of cell viability and membrane integrity in a TSP concentration- or NaOH-alkaline pH-dependent manner. In contrast, cells treated with different concentrations of TSP whose pH was adjusted to 7.0 did not show any loss of cell viability or membrane integrity. These results indicate that TSP is a potent membrane-acting agent, and provide compelling evidence that high pH during TSP treatment was responsible for its antimicrobial activity. Adaptation of S. enterica serovar Enteritidis with a sublethal concentration of TSP resulted in the induction of the alkaline stress response. Alkaline stress response involves induced thermotolerance, resistance to higher concentrations of TSP, high pH and sensitivity to acid. Examination of the proteome of TSP-adapted cells revealed differential expression of a number of proteins but did not include the common heat shock proteins involved in thermotolerance. However, TSP adaptation caused a shift in the membrane fatty acid composition from unsaturated to a higher saturated and cyclic fatty acid. This shift in fatty acid composition increases the melting point of the cytoplasmic membrane so that it remains functional at high temperatures. Biofilm bacteria are more resistant to sanitizers, heat and antimicrobial agents than their planktonic counterparts. Examination of the proteome of TSP-adapted biofilm cell of S. enterica serovar Enteritidis revealed little overlap in the protein profile compared to TSP-adapted planktonic cells. Proteomic examination of planktonic and biofilm cells of S. enterica serovar Enteritidis revealed differential expression of a number of proteins involved in DNA replication, stress survival and transport of newly synthesized proteins. These results clearly indicate that changes in the expression of specific genes are involved in the biofilm mode of growth, which could play a significant role in resistance to antimicrobial agents. The results of the current study provide a better understanding of the mechanisms of antimicrobial action of TSP and also elucidate the response of S. enterica serovar Enteritidis to TSP and high pH adaptation. The study also raises new questions regarding stress tolerance of S. Enteritidis following TSP or alkaline pH adaptation with relevance to food safety.

Mass-spectrometric analysis of proteins

Two-dimensional gel electrophoresis

Molecular and physiological responses of <i>salmonella enterica serovar</i> enteritidis ATCC 4931 to <i>trisodium phosphate</i>

Sampathkumar, Balamurugan

08 September 2003

Salmonella species continue to be commonly associated with cases of food-borne disease in developed countries. In the United States in 2001, the incidence per 100,000 people was highest for salmonellosis (15.1), followed by campylobacteriosis (13.8) and shigellosis (6.4). Enteric pathogens usually contaminate the surface of raw animal products during slaughter and primary processing (scalding, defeathering or dehiding, rinsing, cutting, mixing, and grinding, etc.) and can attach and/or reside in the regular and irregular surfaces of the skin, multiply and, thereafter, contaminate food preparation surfaces, hands and utensils. Trisodium phosphate (TSP) has been approved by the USDA as a sanitizer to reduce surface loads of Salmonella on chicken carcasses. A number of studies had demonstrated that TSP effectively removes surface contamination of carcasses by food-borne pathogens. However, very little scientific evidence is available which identifies the actual mechanisms of TSP antimicrobial activity and the response of food-borne pathogens exposed to TSP. This study examined both the physiological and molecular response of Salmonella enterica serovar Enteritidis to TSP treatment. The role of high pH during TSP treatment on its antimicrobial activity was examined. Adaptation of S. enterica serovar Enteritidis to TSP treatment was also examined by analyzing the proteome of serovar Enteritidis cells using two-dimensional gel electrophoresis and mass spectrometry. The role of high pH on the antimicrobial activity of TSP was examined using comparative studies involving treatment solutions containing different concentrations of TSP, treatment solutions adjusted to the equivalent pH as in each of the TSP treatments and TSP solutions pH adjusted to 7.0. Direct and indirect indices of cell survival, membrane damage, and cellular leakage were also employed to examine specific antimicrobial effects. Cell viability, loss of membrane integrity, cellular leakage, release of lipopolysaccharides and cell morphology were accordingly examined and quantified under the above treatment conditions. Exposure of serovar Enteritidis cells to TSP or equivalent alkaline pH made with NaOH resulted in the loss of cell viability and membrane integrity in a TSP concentration- or NaOH-alkaline pH-dependent manner. In contrast, cells treated with different concentrations of TSP whose pH was adjusted to 7.0 did not show any loss of cell viability or membrane integrity. These results indicate that TSP is a potent membrane-acting agent, and provide compelling evidence that high pH during TSP treatment was responsible for its antimicrobial activity. Adaptation of S. enterica serovar Enteritidis with a sublethal concentration of TSP resulted in the induction of the alkaline stress response. Alkaline stress response involves induced thermotolerance, resistance to higher concentrations of TSP, high pH and sensitivity to acid. Examination of the proteome of TSP-adapted cells revealed differential expression of a number of proteins but did not include the common heat shock proteins involved in thermotolerance. However, TSP adaptation caused a shift in the membrane fatty acid composition from unsaturated to a higher saturated and cyclic fatty acid. This shift in fatty acid composition increases the melting point of the cytoplasmic membrane so that it remains functional at high temperatures. Biofilm bacteria are more resistant to sanitizers, heat and antimicrobial agents than their planktonic counterparts. Examination of the proteome of TSP-adapted biofilm cell of S. enterica serovar Enteritidis revealed little overlap in the protein profile compared to TSP-adapted planktonic cells. Proteomic examination of planktonic and biofilm cells of S. enterica serovar Enteritidis revealed differential expression of a number of proteins involved in DNA replication, stress survival and transport of newly synthesized proteins. These results clearly indicate that changes in the expression of specific genes are involved in the biofilm mode of growth, which could play a significant role in resistance to antimicrobial agents. The results of the current study provide a better understanding of the mechanisms of antimicrobial action of TSP and also elucidate the response of S. enterica serovar Enteritidis to TSP and high pH adaptation. The study also raises new questions regarding stress tolerance of S. Enteritidis following TSP or alkaline pH adaptation with relevance to food safety.

Mass-spectrometric analysis of proteins

Two-dimensional gel electrophoresis

Identification of potential plasma biomarkers of inflammation in farmers with musculoskeletal disorders : A proteomic study

Carlsson, Anders

January 2012

In this thesis we look for potential chronic inflammation biomarkers because studies have shown that farmers with musculoskeletal disorders might be affected by the environment to develop musculoskeletal disorders. Animal farmers are highly exposed to dust, aerosols, molds and other toxins in the air and environment leading to musculoskeletal disorders, respiratory disorders, airway symptoms and febrile reactions. There is reason to believe that the farmers have a constant or chronic inflammation that develops into musculoskeletal disorders. By using a proteomic approach with Two-dimensional Gel Electrophoresis and silver staining our goal was to find biomarkers by quantifying protein spots that differ significantly from farmers with musculoskeletal disorders compared to rural controls. In our study we found 8 significant proteins, two from Alpha-2-HS-glycoprotein, one from Apolipoprotein A1, three from Haptoglobin, one from Hemopexin and 1 from Antithrombin. All 5 proteins are involved in inflammation response in some way and some proteins are linked to chronic inflammation. Out of the 5 proteins Alpha-2-HS-glycoprotein, Apolipoprotein A1 and Hemopexin seem like the most likely proteins to investigate further as potential inflammation biomarkers.

Proteomics

biomarkers

two-dimensional gel electrophoresis

musculoskeletal disorders

environment

Identification and characterization of proteomic regulations in the cerebellum region of brain in MM1 and VV2 subtypes of sporadic Creutzfeldt-Jakob disease (sCJD) / Proteome Profiling of sCJD brain tissue

Tahir, Waqas

02 June 2016

La maladie sporadique de Creutzfeldt-Jakob (sCJD) est une encéphalopathie spongiforme transmissible mortelle caractérisée par une large gamme de manifestations cliniques et pathologiques. Les caractéristiques pathologiques de la SDMC dépendent en grande partie de la présence d'une forme mal repliée de protéine prion cellulaire (PrPC); Connu sous le nom de PrPSC et polymorphisme (méthionine et valine) au codon 129 du gène PRNP qui code pour PrPC. Les facteurs étiologiques exacts de la MCSJ sont encore inconnus. Le génotype Codon 129 du gène PRNP et le type de PrPSC (type 1 ou type 2) influent sur l'hétérogénéité de la maladie telle que définie par des caractéristiques pathologiques spécifiques de la région qui peuvent réguler les voies moléculaires qui conduisent au développement de phénotypes pathogènes dépendants des sous-types. Dans cette étude, nous avons étudié l'ensemble de la réglementation protéomique dans la région cerebrale du cerveau des deux sous-types les plus répandus (MM1 et VV2) des patients atteints de SDMC utilisant une électrophorèse sur gel bidimensionnelle (2DE) et une spectrométrie de masse. L'analyse de toutes les taches de protéines sur les gels 2DE avec le logiciel DECODON Delta2D a révélé vingt-cinq taches de protéines différenciées et l'identification de ces taches avec MALDI-TOF MS / MS a révélé quatre-vingts trois protéines différentiellement réglementées dans les deux sous-types dans la région du cervebelle du cerveau par les patients atteints de sCJD. Quarante protéines dans le sous-type MM1 et quarante-trois protéines dans le sous-type VV2 ont été classées. Douze protéines étaient communément réglementées dans les deux sous-types, dont cinq d'entre elles présentaient une régulation expresnelle inverse et le repos sept avait une régulation expresnelle similaire dans les deux sous-types. Les trois principaux mécanismes moléculaires cellulaires réglementés dans les deux sous-types comprennent: i) le cycle cellulaire; L'expression des gènes et la mort cellulaire, ii) - la réponse au stress cellulaire / le stress oxydatif et iii) - la transduction du signal et les fonctions synaptiques La plupart des protéines sous la classification des réponses au stress cellulaire étaient associées aux fonctions moléculaires cellulaires liées au stress oxydatif. DJ-1 qui est un capteur bien connu de stress oxydatif, a également été jugé réglementé dans la catégorie des réponses au stress cellulaire. Le DJ-1 protège les cellules contre le stress oxydatif directement en translocant au noyau pour l'activation de gènes antioxydants et indirectement en activant la voie Nrf2 / ARE. Nos résultats expérimentaux ont démontré l'activation de la voie Nrf2 / ARE dans les sous-types MM1 et VV2 de sCJD. Le DJ-1 a également montré une régulation positive significative dans son expression de l'ARNm dans les sous-types MM1 et VV2 mais l'expression des protéines uniquement dans le sous-type VV2 dans le cervelet du cerveau des patients atteints de sCJD. En outre, l'expression de la protéine DJ-1 a également été augmentée au cours des stades pré-symptomatiques et symptomatiques dans le cervelet du cerveau des modèles de souris de sCJD (MM1 et VV2) et pendant le stade clinique dans les échantillons de CSF des patients atteints de SDMC. Ces résultats suggèrent l'implication du stress oxydatif lors de la pathophysiologie de la SDMC et l'utilisation de DJ-1 comme capteur potentiel de stress oxydatif pendant la phase clinique de la sCJD.

570

Biologie (PPN619462639)

Comparative study on the sonic muscles of glaucosomatid, pempherid, terapontid, and ophidiid: a proteomic approach

Dian Pertiwi, Titisari

13 December 2012

Some fishes use sound to communicate. The majority of these soniferous fishes use superfast sonic muscles to set the vibration of the swim bladder which results in sound emission and sound amplification. Carapus, a benthic ophiidiform genus, use a slow contracting sonic muscle to pull the anteriormost part of the swim bladder, upon termination of the pulling action, the front part of the swim bladder is snap back setting the swimbladder fenestrum to vibrate. This vibration gives rise to the sound. Other ophiidiform fishes may also use a similar way to emit sounds. Among the soniferous percoids, an advanced perform suborder, glaucosomatid, pempherid, and terapontid share a fenestrum-like structure in the front part of their swim bladder. Previous molecular study suggested that the first two groups form a clade (monophyletic group). It is of great interest to compare the proteomic features of these groups with that of the ophiidiform representatives so that the effects of function and phylogeny to the proteomic characteristics of the sonic muscle can be compared. A species was selected for each of these four groups and their proteomics were analyzed. Results of this study, however, revealed the protein composition of the sonic muscles in the ophiidiform species was more similar to that of the pempherid species. The proteins contribute to the close relationship between these two groups was discussed. A total of 484 protein spots were found in these four species and only five were presented in the sonic muscles of all four species, but absent in the white muscles; and only three of them were successfully identified as: Flotillin-1 (spot 6), HBS1-like protein (spot 8), and Ras-related protein ralB-B (spot 10). Their functions which may be related to the specific role of the sonic muscle were discussed.

sonic muscle

ophiidiform

glaucosomatid

pempherid

terapontid

Dissecting the molecular interplay between tomato spotted wilt virus and the insect vector, Frankliniella occidentalis

Badillo-Vargas, Ismael

January 1900

Doctor of Philosophy / Department of Plant Pathology / Anna E. Whitfield / The Bunyaviridae is a family of animal and plant viruses that pose a threat to human, animal, and plant health worldwide. In nature, the dissemination of these viruses is dependent on arthropod vectors (genera Orthobunyavirus, Nairovirus, Phlebovirus, and Tospovirus) or rodent vectors (genus Hantavirus). The genus Tospovirus is the only one within this virus family that is composed of plant-infecting viruses transmitted by thrips. Tomato spotted wilt virus (TSWV), the type species of the Tospovirus genus, is one of the ten most devastating plant viruses known. It is most efficiently transmitted by the western flower thrips, Frankliniella occidentalis Pergande, in a persistant propagative manner. The insect molecules associated with virus infection and transmission by the thrips vector remain unidentified to date. The aim of this work was to identify F. occidentalis larval thrips proteins that are differentially expressed during TSWV infection of the insect vector and those that directly interact with TSWV. To achieve these goals, I used two-dimensional (2-D) gel electrophoresis and mass spectrometry coupled with Mascot searches. I identified 26 protein spots that displayed differential abundances in response to TSWV infection, which contained 37 proteins. Sixty two percent of these proteins were down-regulated by the viral infection demonstrating a complex response. Moreover, 8 and 11 protein spots that directly interacted with purified TSWV virions and a TSWV glycoprotein (GN), respectively, were identified in overlay assays of larval thrips proteins resolved by 2-D gel electrophoresis. A total of five proteins were identified from these spots. These interacting proteins might play roles in attachment and entry, endocytosis/exocytosis, and escape from different tissues for transmission to occur. Injection of double-stranded RNA (dsRNA) into adult female thrips triggered an RNAi response that resulted in 23% reduction of the target gene transcript level. This significant reduction resulted in increased mortality and decreased fertility compared to insects injected with control dsRNA or water and non-injected insects as well. The work presented here provides new insights on the molecular basis of this virus-vector interaction and describes new tools to conduct functional genomic assays to study gene function and design control strategies of F. occidentalis.

Tospovirus

Thrips

Persistent propagative transmission

Proteomics

Two-dimensional gel electrophoresis

RNA interference

Exploring Metallic Flavor Perception: Analysis of Human Salivary Proteins and the Use of the Iron-Binding Protein Lactoferrin in Reducing Metallic Off-Flavors

Martin, Kerri Katherine

29 August 2012

Metallic flavors are of concern for many industries including food, health, and water. Metallic off-flavor, induced by ferrous sulfate solution (10mg/L), and its remediation using pre- and post-rinse treatments of water (control) or metal chelators, were studied. Metal chelators included lactoferrin (1 ?M), a natural metal-binding protein in milk and saliva, and EDTA (36 ?M), a synthetic chelator. Time-intensity (TI) evaluation (n=6, 4 female; age 40-70) of lingering metallic flavor indicated that metallic flavor decreased with a post-rinse adjuvant treatment of lactoferrin as indicated by a reduced maximum intensity and area under the curve compared to a pre-rinse treatment; EDTA and water post-rinses were equally effective for three of the TI parameters. Alterations in salivary components were studied in saliva collected (n=8; 5 female, age 40-70) after sipping a lactoferrin solution (1?M) followed with a ferrous sulfate sample (10 mg/ml) to stimulate metallic flavor, as compared to unstimulated whole saliva. Protein concentration, oral lipid oxidation as indicated by thiobarbituric acid reactive substances assay, and iron concentration were determined on individual saliva samples, with no significant differences found between treatments (p>0.05). Protein patterns were qualitatively characterized for each pre-rinse and metallic stimuli from four panelists by two-dimensional gel electrophoresis. A consistent pattern of regions containing major salivary components was observed. This research has shown that lactoferrin protein is a potential natural alternative to synthetic EDTA for reducing iron-induced metallic off-flavors. This study provides a foundation of method development to better understand salivary protein interaction with metals and flavor perception. / Master of Science in Life Sciences

metallic flavor

human salivary proteins

two-dimensional gel electrophoresis

lactoferrin

time-intensity

Effects of Bilateral Lesion of the Locus Coeruleus and of Neonatal Administration of 6-Hydroxydopamine on the Concentration of Individual Proteins in Rat Brain

Heydorn, William E., Nguyen, Khanh Q., Joseph Creed, G., Kostrzewa, Richard M., Jacobowitz, David M.

05 March 1986

The role that norepinephrine plays in regulating the concentration of different proteins in the parietal cortex, hippocampus and cerebellum was assessed by investigating the effects of either a bilateral lesion of the locus coeruleus or neonatal administration of 6-hydroxydopamine. Two weeks after lesioning the locus coeruleus, the concentration of two different proteins was elevated in the hippocampus; a third protein was reduced in concentration in this brain area as a result of the lesion. Three proteins were affected in concentration in the cerebellum after the locus coeruleus lesion - two were elevated in concentration and one was reduced in concentration. No proteins were altered in concentration in the parietal cortex as a result of the lesion. Seventy days after neonatal treatment with 6-hydroxydopamine, a total of 6 proteins were found to be changed. Four of these (one in the hippocampus and 3 in the parietal cortex) were reduced in concentration while two proteins (both in the cerebellum) were elevated in concentration after neonatal treatment with the catecholamine neurotoxin. There was little overlap between those proteins affected in concentration by the bilateral lesion of the locus coeruleus and those changed by neonatal treatment with 6-hydroxydopamine. These results suggest that the concentration of a number of different proteins may, under normal physiological conditions, be regulated in vivo by norepinephrine in the brain.

central nervous system protein

locus coeruleus lesion

neonatal 6-hydroxydopamine

norepinephrine

scanning densitometry

two-dimensional gel electrophoresis

Biomedical Sciences