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71-494: OmpT is a 33.5 kDa outer membrane protein consisting of 10 antiparallel strands that are connected by 5 extracellular loops. The antiparallel strands form a beta barrel structure that spans the width of the membrane, creating a pore. E. coli omptins can be coded either from the OmpT gene on a chromosome (part of a DLP12 prophage ) or from OmpP on a plasmid (OmpP). The sequences resulting from these two sources differ by 24-25% in

142-443: A "proteomics" study may become complex very quickly, even if the topic of study is restricted. In more ambitious settings, such as when a biomarker for a specific cancer subtype is sought, the proteomics scientist might elect to study multiple blood serum samples from multiple cancer patients to minimise confounding factors and account for experimental noise. Thus, complicated experimental designs are sometimes necessary to account for

213-417: A beta barrel can be formed by bringing the edges of a beta sheet together to form a cylinder. If those edges are displaced, shear is created. A similar definition is found in geology, where shear refers to a displacement within rock perpendicular to the rock surface. In physics, the amount of displacement is referred to as shear strain , which has units of length. For shear number in barrels, displacement

284-420: A cell must be identified. In the past this phenomenon was assessed by RNA analysis, which was found to lack correlation with protein content. It is now known that mRNA is not always translated into protein, and the amount of protein produced for a given amount of mRNA depends on the gene it is transcribed from and on the cell's physiological state. Proteomics confirms the presence of the protein and provides

355-431: A cellular membrane. Such structures appear in the outer membranes of gram-negative bacteria, chloroplasts , and mitochondria . The central pore of the protein, sometimes known as the eyelet , is lined with charged residues arranged so that the positive and negative charges appear on opposite sides of the pore. A long loop between two beta strands partially occludes the central channel; the exact size and conformation of

426-538: A closed toroidal structure in which the first strand is bonded to the last strand ( hydrogen bond ). Beta-strands in many beta-barrels are arranged in an antiparallel fashion. Beta barrel structures are named for resemblance to the barrels used to contain liquids. Most of them are water-soluble outer membrane proteins and frequently bind hydrophobic ligands in the barrel center, as in lipocalins . Others span cell membranes and are commonly found in porins . Porin-like barrel structures are encoded by as many as 2–3% of

497-420: A comparative proteomic analysis of mated N. lugens females. The results indicated that these proteins participate in the reproductive process of N. lugens adult females and males. Proteome analysis of Arabidopsis peroxisomes has been established as the major unbiased approach for identifying new peroxisomal proteins on a large scale. There are many approaches to characterizing the human proteome, which

568-456: A complex protein mixture is separated using SDS-PAGE and then the protein of interest is identified using an antibody. Modified proteins may be studied by developing an antibody specific to that modification. For example, some antibodies only recognize certain proteins when they are tyrosine- phosphorylated , they are known as phospho-specific antibodies. Also, there are antibodies specific to other modifications. These may be used to determine

639-414: A development that was made possible by the discovery of "soft ionization" methods developed in the 1980s, such as matrix-assisted laser desorption/ionization (MALDI) and electrospray ionization (ESI) . These methods gave rise to the top-down and the bottom-up proteomics workflows where often additional separation is performed before analysis (see below). For the analysis of complex biological samples,

710-418: A direct measure of its quantity. Not only does the translation from mRNA cause differences, but many proteins also are subjected to a wide variety of chemical modifications after translation. The most common and widely studied post-translational modifications include phosphorylation and glycosylation. Many of these post-translational modifications are critical to the protein's function. One such modification

781-715: A number of applications beyond the study of tumors. The approach can provide insights into normal physiology and pathology of all the tissues and is invaluable for characterizing developmental processes and anomalies. Recent advancements in bioorthogonal chemistry have revealed applications in protein analysis. The extension of using organic molecules to observe their reaction with proteins reveals extensive methods to tag them. Unnatural amino acids and various functional groups represent new growing technologies in proteomics. Specific biomolecules that are capable of being metabolized in cells or tissues are inserted into proteins or glycans. The molecule will have an affinity tag, modifying

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852-400: A number of small, organic pheromones , including 2-sec-butyl-4,5-dihydrothiazole (abbreviated as SBT or DHT), 6-hydroxy-6-methyl-3-heptanone (HMH) and 2,3 dihydro-exo-brevicomin (DHB). A piece of paper can be formed into a cylinder by bringing opposite sides together. The two edges come together to form a line. Shear can be created by sliding the two edges parallel to that line. Likewise,

923-620: A reduction of sample complexity is required. This may be performed off-line by one-dimensional or two-dimensional separation. More recently, on-line methods have been developed where individual peptides (in bottom-up proteomics approaches) are separated using reversed-phase chromatography and then, directly ionized using ESI ; the direct coupling of separation and analysis explains the term "on-line" analysis. Several hybrid technologies use antibody-based purification of individual analytes and then perform mass spectrometric analysis for identification and quantification. Examples of these methods are

994-438: A researcher determines which substrates are ubiquitinated by each ligase, determining the set of ligases expressed in a particular cell type is helpful. In addition to phosphorylation and ubiquitination , proteins may be subjected to (among others) methylation , acetylation , glycosylation , oxidation , and nitrosylation . Some proteins undergo all these modifications, often in time-dependent combinations. This illustrates

1065-793: A very specific antibody needs to be used in quantitative dot blot analysis (QDB), or biochemical separation then needs to be used before the detection step, as there are too many analytes in the sample to perform accurate detection and quantification. Antibodies to particular proteins, or their modified forms, have been used in biochemistry and cell biology studies. These are among the most common tools used by molecular biologists today. There are several specific techniques and protocols that use antibodies for protein detection. The enzyme-linked immunosorbent assay (ELISA) has been used for decades to detect and quantitatively measure proteins in samples. The western blot may be used for detection and quantification of individual proteins, where in an initial step,

1136-420: Is phosphorylation , which happens to many enzymes and structural proteins in the process of cell signaling . The addition of a phosphate to particular amino acids—most commonly serine and threonine mediated by serine-threonine kinases , or more rarely tyrosine mediated by tyrosine kinases —causes a protein to become a target for binding or interacting with a distinct set of other proteins that recognize

1207-462: Is difficult to preserve on glass slides, though they are essential for most assays. The global ICAT technology has striking advantages over protein chip technologies. This is a promising and newer microarray application for the diagnosis, study and treatment of complex diseases such as cancer. The technology merges laser capture microdissection (LCM) with micro array technology, to produce reverse-phase protein microarrays. In this type of microarrays,

1278-410: Is estimated to contain between 20,000 and 25,000 non-redundant proteins. The number of unique protein species likely will increase by between 50,000 and 500,000 due to RNA splicing and proteolysis events, and when post-translational modification also are considered, the total number of unique human proteins is estimated to range in the low millions. In addition, the first promising attempts to decipher

1349-517: Is measured in units of amino acid residues. The determination of shear number requires the assumption that each amino acid in one strand of a beta sheet is adjacent to just one amino acid in the neighboring strand (this assumption may not hold if, for example, a beta bulge is present). To illustrate, S will be calculated for green fluorescent protein . This protein was chosen because the beta barrel contains both parallel and antiparallel strands. To determine which amino acid residues are adjacent in

1420-546: Is not at the same level: it is 14 residues higher than it started at, so its shear number, S , is 14. Proteomics Proteomics is the large-scale study of proteins . Proteins are vital macromolecules of all living organisms, with many functions such as the formation of structural fibers of muscle tissue , enzymatic digestion of food, or synthesis and replication of DNA . In addition, other kinds of proteins include antibodies that protect an organism from infection, and hormones that send important signals throughout

1491-425: Is only cleaved in the presence of its bacterial target. OmpT has been identified as a potential probe to use in mass spectrometry-based proteomics , because its substrate specificity allows it to differentiate between proteins with related primary sequences. Beta barrel In protein structures, a beta barrel (β barrel) is a beta sheet (β sheet) composed of tandem repeats that twists and coils to form

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1562-422: Is the ability to analyze hundreds or thousands of samples in a reasonable timeframe (a matter of days or weeks); mass spectrometry-based methods are not scalable to this level of sample throughput for proteomics analyses. Balancing the use of mass spectrometers in proteomics and in medicine is the use of protein micro arrays. The aim behind protein micro arrays is to print thousands of protein detecting features for

1633-732: Is the accurate mass and time (AMT) tag approach developed by Richard D. Smith and coworkers at Pacific Northwest National Laboratory . In this approach, increased throughput and sensitivity is achieved by avoiding the need for tandem mass spectrometry, and making use of precisely determined separation time information and highly accurate mass determinations for peptide and protein identifications. Affinity proteomics uses antibodies or other affinity reagents (such as oligonucleotide-based aptamers) as protein-specific detection probes. Currently this method can interrogate several thousand proteins, typically from biofluids such as plasma, serum or cerebrospinal fluid (CSF). A key differentiator for this technology

1704-495: Is the most powerful method for analysis of proteomes, both in large samples composed of millions of cells and in single cells. The first studies of proteins that could be regarded as proteomics began in 1974, after the introduction of the two-dimensional gel and mapping of the proteins from the bacterium Escherichia coli . Proteome is a blend of the words "protein" and "genome". It was coined in 1994 by then-Ph.D student Marc Wilkins at Macquarie University , which founded

1775-576: Is useful in monitoring the status of key factors in normal prostate epithelium and invasive prostate cancer tissues. LCM then dissects these tissue and protein lysates were arrayed onto nitrocellulose slides, which were probed with specific antibodies. This method can track all kinds of molecular events and can compare diseased and healthy tissues within the same patient enabling the development of treatment strategies and diagnosis. The ability to acquire proteomics snapshots of neighboring cell populations, using reverse-phase microarrays in conjunction with LCM has

1846-429: Is worthwhile noting the limitations and benefits. Rapid reactions can create bioconjuctions and create high concentrations with low amounts of reactants. Contrarily slow kinetic reactions like aldehyde and ketone condensation while effective require a high concentration making it cost inefficient. One major development to come from the study of human genes and proteins has been the identification of potential new drugs for

1917-471: The Human Genome Project . It covers the exploration of proteomes from the overall level of protein composition, structure, and activity, and is an important component of functional genomics . Proteomics generally denotes the large-scale experimental analysis of proteins and proteomes, but often refers specifically to protein purification and mass spectrometry . Indeed, mass spectrometry

1988-589: The MSIA (mass spectrometric immunoassay) , developed by Randall Nelson in 1995, and the SISCAPA (Stable Isotope Standard Capture with Anti-Peptide Antibodies) method, introduced by Leigh Anderson in 2004. Fluorescence two-dimensional differential gel electrophoresis (2-D DIGE) may be used to quantify variation in the 2-D DIGE process and establish statistically valid thresholds for assigning quantitative changes between samples. Comparative proteomic analysis may reveal

2059-399: The nucleophilic attack of water at the carbonyl between two adjacent amino acid residues. Water enters the protease from the intracellular surface and is stabilized by Asp83 and His212. During the proton transfer associated with the peptide cleavage, the negatively charged aspartate residue stabilizes the positively charged histidine. Once docked in this position, water is positioned to attack

2130-533: The primary sequence . The jelly roll fold or barrel, also known as the Swiss roll, typically comprises eight beta strands arranged in two four-stranded sheets. Adjacent strands along the sequence alternate between the two sheets, such that they are "wrapped" in three dimensions to form a barrel shape. Sixteen- or eighteen-stranded up-and-down beta barrel structures occur in porins, which function as transporters for ions and small molecules that cannot diffuse across

2201-455: The tissue factor pathway inhibitor (TFPI), counteracting the host's immune response, and further perpetuating the spread of extraintestinal E. coli infection. In zebrafish, ZF-RNase-3 ( A5HAK0 ) must be cleaved by a protease (such as OmpT) in order to become activated and serve its bactericidal function. Through this evolved suicidal mechanism, the RNase mediates its own activation, since it

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2272-538: The ICAT reagent, thereby reducing the complexity of the mixtures omitting the non-cysteine residues. Quantitative proteomics using stable isotopic tagging is an increasingly useful tool in modern development. Firstly, chemical reactions have been used to introduce tags into specific sites or proteins for the purpose of probing specific protein functionalities. The isolation of phosphorylated peptides has been achieved using isotopic labeling and selective chemistries to capture

2343-409: The active site of the protease is anionic. This causes OmpT to selectively cleave peptides between two basic (positively charged) residues. The active site of OmpT resembles that of other omptins, and is characterized by conserved residues at Asp84, Asp86, Asp206, and His208. The most common bond cleavage by OmpT is between two arginine residues because their positive charge can favorably interact with

2414-497: The advances in 2-DE and its maturity, it has its limits as well. The central concern is the inability to resolve all the proteins within a sample, given their dramatic range in expression level and differing properties. The combination of pore size, and protein charge, size and shape can greatly determine migration rate which leads to other complications. The second quantitative approach uses stable isotope tags to differentially label proteins from two different complex mixtures. Here,

2485-427: The bacteria encounters. Because of its ability to cleave peptides present in its surrounding environment, OmpT is associated with several pathologies. Urinary tract infections (UTIs) are often due to E. coli entering the urethra and colonizing. The host's immune system will release protamines and other antimicrobials to combat the infection, but OmpT easily degrades the cationic protamine peptides, thus enhancing

2556-623: The best characterised of which is Toc75 of the TOC complex (Translocon at the outer envelope membrane of chloroplasts). Lipocalins are typically eight-stranded up-and-down beta barrel proteins that are secreted into the extracellular environment. A distinctive feature is their ability to bind and transport small hydrophobic molecules in the barrel calyx . Examples of the family include retinol binding proteins (RBPs) and major urinary proteins (Mups). RBP binds and transports retinol (vitamin A), while Mups bind

2627-516: The beta strands, the location of hydrogen bonds is determined. The inter-strand hydrogen bonds can be summarised in a table. Each column contains the residues in one strand (strand 1 is repeated in the last column). The arrows indicate the hydrogen bonds that were identified in the figures. The relative direction of each strand is indicated by the "+" and "-" at the bottom of the table. Except for strands 1 and 6, all strands are antiparallel. The parallel interaction between strands 1 and 6 accounts for

2698-417: The body. The proteome is the entire set of proteins produced or modified by an organism or system. Proteomics enables the identification of ever-increasing numbers of proteins. This varies with time and distinct requirements, or stresses, that a cell or organism undergoes. Proteomics is an interdisciplinary domain that has benefited greatly from the genetic information of various genome projects, including

2769-464: The concentration must be high. Certain proteins can be detected via their reactivity to azide groups . Non-proteinogenic amino acids can bear azide groups which react with phosphines in Staudinger ligations . This reaction has already been used to label other biomolecules in living cells and animals. The bioorthoganal field is expanding and is driving further applications within proteomics. It

2840-404: The defensive response of plants to herbivory. A branch of proteomics called chemoproteomics provides numerous tools and techniques to detect protein targets of drugs. Interaction proteomics is the analysis of protein interactions from scales of binary interactions to proteome- or network-wide. Most proteins function via protein–protein interactions , and one goal of interaction proteomics

2911-447: The different appearance of the hydrogen bonding pattern. (Some arrows are missing because not all of the hydrogen bonds expected were identified. Non-standard amino acids are indicated with "?") The side chains that point to the outside of the barrel are in bold. If no shear were present in this barrel, then residue 12 V, say, in strand 1 should end up in the last strand at the same level as it started at. However, because of shear, 12 V

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2982-709: The dynamic complexity of the proteome. Proteomics gives a different level of understanding than genomics for many reasons: Reproducibility . One major factor affecting reproducibility in proteomics experiments is the simultaneous elution of many more peptides than mass spectrometers can measure. This causes stochastic differences between experiments due to data-dependent acquisition of tryptic peptides. Although early large-scale shotgun proteomics analyses showed considerable variability between laboratories, presumably due in part to technical and experimental differences between laboratories, reproducibility has been improved in more recent mass spectrometry analysis, particularly on

3053-441: The enzyme, inactivates the enzyme. This is the basis of new drug-discovery tools, which aim to find new drugs to inactivate proteins involved in disease. As genetic differences among individuals are found, researchers expect to use these techniques to develop personalized drugs that are more effective for the individual. Proteomics is also used to reveal complex plant-insect interactions that help identify candidate genes involved in

3124-432: The first dedicated proteomics laboratory in 1995. After genomics and transcriptomics , proteomics is the next step in the study of biological systems. It is more complicated than genomics because an organism's genome is more or less constant, whereas proteomes differ from cell to cell and from time to time. Distinct genes are expressed in different cell types, which means that even the basic set of proteins produced in

3195-557: The fraction of protein among the complex mixture. Secondly, the ICAT technology was used to differentiate between partially purified or purified macromolecular complexes such as large RNA polymerase II pre-initiation complex and the proteins complexed with yeast transcription factor. Thirdly, ICAT labeling was recently combined with chromatin isolation to identify and quantify chromatin-associated proteins. Finally ICAT reagents are useful for proteomic profiling of cellular organelles and specific cellular fractions. Another quantitative approach

3266-476: The genes in Gram-negative bacteria. It has been shown that more than 600 proteins with various function such as oxidase, dismutase, and amylase contain the beta barrel structure. In many cases, the strands contain alternating polar and non-polar ( hydrophilic and hydrophobic ) amino acids , so that the hydrophobic residues are oriented into the interior of the barrel to form a hydrophobic core and

3337-436: The host releases antimicrobial peptides as part of the innate immune response. Since OmpT can break down these antimicrobials and inactivate them, EHEC and EPEC can colonize within the colon or small intestine of the host and lead to serious diarrheal diseases. In the case of sepsis , the host activates the blood clotting system to deposit fibrin and limit the spread of bacteria throughout the blood. However, OmpT can inactivate

3408-423: The interrogation of biological samples. Antibody arrays are an example in which a host of different antibodies are arrayed to detect their respective antigens from a sample of human blood. Another approach is the arraying of multiple protein types for the study of properties like protein-DNA, protein-protein and protein-ligand interactions. Ideally, the functional proteomic arrays would contain the entire complement of

3479-607: The loop helps in discriminating between molecules passing through the transporter. Beta barrels also function within endosymbiont derived organelles such as mitochondria and chloroplasts to transport proteins. Within the mitochondrion two complexes exist with beta barrels serving as the pore forming subunit, Tom40 of the Translocase of the outer membrane , and Sam50 of the Sorting and assembly machinery . The chloroplast also has functionally similar beta barrel containing complexes,

3550-558: The mature protease. Genetic differences between OmpT and other members of the omptin family are found in the extracellular loops, and therefore, this area is thought to be associated with substrate specificity. Also, the barrel is relatively rigid, while the loops have more flexibility to bind to substrates of varying sizes. While originally thought to be a serine protease, OmpT is better characterized as an aspartyl protease because of its cleavage mechanism. The substrate of OmpT binds to negatively charged aspartate and glutamate residues, so

3621-441: The molecular level is driving the emerging revolution of early diagnosis and treatment. A challenge facing the field is that protein biomarkers for early diagnosis may be present in very low abundance. The lower limit of detection with conventional immunoassay technology is the upper femtomolar range (10 M). Digital immunoassay technology has improved detection sensitivity three logs, to the attomolar range (10 M). This capability has

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3692-422: The most common technologies for large-scale study of proteins. There are two mass spectrometry-based methods currently used for protein profiling. The more established and widespread method uses high resolution, two-dimensional electrophoresis to separate proteins from different samples in parallel, followed by selection and staining of differentially expressed proteins to be identified by mass spectrometry. Despite

3763-407: The need for awareness that proteomics experiments should adhere to the criteria of analytical chemistry (sufficient data quality, sanity check, validation). In proteomics, there are multiple methods to study proteins. Generally, proteins may be detected by using either antibodies (immunoassays), electrophoretic separation or mass spectrometry . If a complex biological sample is analyzed, either

3834-469: The negatively charged species at the active site during substrate binding. Because of the specificity of the active site, OmpT does not act on peptides with a negatively charged residue adjacent to the scissile bond . Also, OmpT is specifically identified an endopeptidase because it does not cleave peptides at the N- or C-terminus, but only between nonterminal amino acids. The peptide bond cleavage occurs via

3905-438: The number of strands in the beta-sheet, n, and the "shear number", S , a measure of the stagger of the strands in the beta-sheet. These two parameters (n and S) are related to the inclination angle of the beta strands relative to the axis of the barrel. Up-and-down barrels are the simplest barrel topology and consist of a series of beta strands, each of which is hydrogen-bonded to the strands immediately before and after it in

3976-402: The peptide in the active site. The cleavage of peptide bonds by OmpT is also dependent on the presence of bound lipopolysaccharide (LPS). When LPS is not present, the peptide binds too deeply within the active site, and the water cannot reach the carbonyl for its nucleophilic attack of the scissile bond. In E. coli , OmpT is a housekeeping protease that degrades foreign peptide material that

4047-662: The phosphorylated domain. Because protein phosphorylation is one of the most studied protein modifications, many "proteomic" efforts are geared to determining the set of phosphorylated proteins in a particular cell or tissue-type under particular circumstances. This alerts the scientist to the signaling pathways that may be active in that instance. Ubiquitin is a small protein that may be affixed to certain protein substrates by enzymes called E3 ubiquitin ligases . Determining which proteins are poly-ubiquitinated helps understand how protein pathways are regulated. This is, therefore, an additional legitimate "proteomic" study. Similarly, once

4118-420: The polar residues are oriented toward the outside of the barrel on the solvent-exposed surface. Porins and other membrane proteins containing beta barrels reverse this pattern, with hydrophobic residues oriented toward the exterior where they contact the surrounding lipids , and hydrophilic residues oriented toward the aqueous interior pore. All beta-barrels can be classified in terms of two integer parameters:

4189-411: The potential complexity of studying protein structure and function. A cell may make different sets of proteins at different times or under different conditions, for example during development , cellular differentiation , cell cycle , or carcinogenesis . Further increasing proteome complexity, as mentioned, most proteins are able to undergo a wide range of post-translational modifications. Therefore,

4260-430: The potential to open new advances in diagnostics and therapeutics, but such technologies have been relegated to manual procedures that are not well suited for efficient routine use. While protein detection with antibodies is still very common in molecular biology, other methods have been developed as well, that do not rely on an antibody. These methods offer various advantages, for instance they often are able to determine

4331-603: The protein allowing it to be detected. Azidohomoalanine (AHA) utilizes this affinity tag via incorporation with Met-t-RNA synthetase to incorporate into proteins. This has allowed AHA to assist in determine the identity of newly synthesized proteins created in response to perturbations and to identify proteins secreted by cells. Recent studies using ketones and aldehydes condensations show that they are best suited for in vitro or cell surface labeling . However, using ketones and aldehydes as bioorthogonal reporters revealed slow kinetics indicating that while effective for labeling,

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4402-469: The protein level. Notably, targeted proteomics shows increased reproducibility and repeatability compared with shotgun methods, although at the expense of data density and effectiveness. Data quality . Proteomic analysis is highly amenable to automation and large data sets are created, which are processed by software algorithms. Filter parameters are used to reduce the number of false hits, but they cannot be completely eliminated. Scientists have expressed

4473-399: The proteins of a given organism. The first version of such arrays consisted of 5000 purified proteins from yeast deposited onto glass microscopic slides. Despite the success of first chip, it was a greater challenge for protein arrays to be implemented. Proteins are inherently much more difficult to work with than DNA. They have a broad dynamic range, are less stable than DNA and their structure

4544-415: The proteins within a complex mixture are labeled isotopically first, and then digested to yield labeled peptides. The labeled mixtures are then combined, the peptides separated by multidimensional liquid chromatography and analyzed by tandem mass spectrometry. Isotope coded affinity tag (ICAT) reagents are the widely used isotope tags. In this method, the cysteine residues of proteins get covalently attached to

4615-460: The proteome of animal tumors have recently been reported. This method was used as a functional method in Macrobrachium rosenbergii protein profiling. Proteomics has steadily gained momentum over the past decade with the evolution of several approaches. Few of these are new, and others build on traditional methods. Mass spectrometry-based methods, affinity proteomics, and micro arrays are

4686-404: The risk of infection. There is a genetic link between OmpT and other UTI-mediating factors (such as kpsMT, cnf1, prf, and sfa ), but the functional link between these proteins is not well defined. Enterohemorrhagic E. coli (EHEC) and enteropathogenic E. coli (EPEC) are pathogens that rely on OmpT to colonize in the intestine of their host. In response to the presence of E. coli in the gut,

4757-543: The role of proteins in complex biological systems, including reproduction. For example, treatment with the insecticide triazophos causes an increase in the content of brown planthopper ( Nilaparvata lugens (Stål)) male accessory gland proteins (Acps) that may be transferred to females via mating, causing an increase in fecundity (i.e. birth rate) of females. To identify changes in the types of accessory gland proteins (Acps) and reproductive proteins that mated female planthoppers received from male planthoppers, researchers conducted

4828-553: The sequence of a protein or peptide, they may have higher throughput than antibody-based, and they sometimes can identify and quantify proteins for which no antibody exists. One of the earliest methods for protein analysis has been Edman degradation (introduced in 1967) where a single peptide is subjected to multiple steps of chemical degradation to resolve its sequence. These early methods have mostly been supplanted by technologies that offer higher throughput. More recently implemented methods use mass spectrometry -based techniques,

4899-409: The set of proteins that have undergone the modification of interest. Immunoassays can also be carried out using recombinantly generated immunoglobulin derivatives or synthetically designed protein scaffolds that are selected for high antigen specificity. Such binders include single domain antibody fragments (Nanobodies), designed ankyrin repeat proteins (DARPins) and aptamers. Disease detection at

4970-429: The treatment of disease. This relies on genome and proteome information to identify proteins associated with a disease, which computer software can then use as targets for new drugs. For example, if a certain protein is implicated in a disease, its 3D structure provides the information to design drugs to interfere with the action of the protein. A molecule that fits the active site of an enzyme, but cannot be released by

5041-465: The whole collection of protein themselves are immobilized with the intent of capturing various stages of disease within an individual patient. When used with LCM, reverse phase arrays can monitor the fluctuating state of proteome among different cell population within a small area of human tissue. This is useful for profiling the status of cellular signaling molecules, among a cross-section of tissue that includes both normal and cancerous cells. This approach

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