prokaryotic transcription.pptx
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This document summarizes prokaryotic transcription. It describes that transcription involves RNA polymerase adding RNA nucleotides to a DNA template, similar to DNA replication but producing RNA. RNA polymerase requires a sigma factor to bind promoter regions containing -10 and -35 sequences. Transcription then proceeds through initiation, elongation, and termination stages. Initiation involves formation of open and closed complexes. Termination can be rho-independent using hairpin structures or rho-dependent using rho protein binding.
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The document summarizes the process of transcription and translation in cells. It describes:
1) Transcription of DNA to RNA which is catalyzed by RNA polymerase and involves the formation of RNA through the addition of ribonucleotides.
2) Processing of eukaryotic pre-mRNA which involves capping, splicing, and polyadenylation to form mature mRNA.
3) Translation of mRNA to protein which occurs on ribosomes and involves tRNAs carrying amino acids that are linked together through peptide bond formation catalyzed by the ribosome. Accuracy is ensured by induced fit binding and kinetic proofreading.
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2. RNA primers are synthesized by the primase enzyme and DNA polymerase adds complementary nucleotides to the 3' end of each primer, elongating it into DNA.
3. The leading strand is synthesized continuously in the 5' to 3' direction while the lagging strand is synthesized in fragments called Okazaki fragments which are later joined by DNA ligase.
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PROKAYOTIC TRANSCRIPTION.pptx
Transcription in prokaryotes involves RNA polymerase copying a portion of the DNA genome into RNA. It occurs in three main steps: initiation, elongation, and termination. Initiation begins with RNA polymerase binding to promoter sequences on DNA to form a closed complex, then an open complex. Elongation entails RNA polymerase continuing to synthesize RNA down the DNA template. Termination can occur via either rho-independent or rho-dependent mechanisms, stopping further RNA production.
transcription in prokaryotes and RNA polymerase of prokaryotes
The core RNA polymerase associates with the sigma factor to generate the RNA polymerase holoenzyme, which is required for recruiting RNA polymerase to the promoter. The sigma factor binds to the -10 and -35 promoter elements. During transcription initiation, RNA polymerase unwinds the DNA and begins RNA synthesis. It then enters elongation, synthesizing RNA processively until it reaches a terminator sequence and dissociates from the DNA. RNA polymerase synthesizes various RNA transcripts including mRNA, tRNA, and rRNA.
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Biochem synthesis of dna
DNA replication occurs semi-conservatively, with each parental strand serving as a template for synthesis of a new complementary strand. This results in two identical DNA molecules, each with one original parental strand and one newly synthesized strand. Replication is initiated at the origin of replication and proceeds bidirectionally around the circular bacterial chromosome. Enzymes such as helicase unwind the parental DNA, topoisomerases relieve supercoiling, and DNA polymerase adds complementary nucleotides using the parental strands as templates.
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DNA replication is the process where one original DNA molecule is copied to produce two identical DNA molecules. It occurs through semiconservative replication where each strand of the original DNA serves as a template for the production of the complementary strand. The replication fork forms during DNA replication through the unwinding of the DNA double helix by helicases. It has two branching prongs that serve as templates for the leading and lagging strands which are synthesized by DNA polymerase.DNA transcription & Post Transcriptional Modification
DNA is transcribed into RNA through the process of transcription. In eukaryotes, transcription is initiated when RNA polymerase binds to a promoter region near a gene. It then elongates the RNA molecule using the DNA as a template. Transcription ends when the polymerase reaches a termination sequence. The primary RNA transcript often undergoes processing like splicing, capping, polyadenylation, and editing to become a functional mRNA, tRNA, or rRNA molecule. These post-transcriptional modifications are required for gene expression.
Dna damage
DNA can be damaged through various means, including single base alterations, double base alterations, chain breaks, and cross-linking. Single base alterations include depurination, deamination, alkylation, base analogue incorporation, and mismatch bases. Double base alterations include pyrimidine dimers and purine dimers caused by UV radiation. Chain breaks include single and double stranded breaks caused by irradiation and free radicals. Cross-linking can occur between DNA and DNA or DNA and proteins due to UV radiation, ionizing radiation, and free radicals. Unrepaired damage can lead to mutations if incorrectly repaired during replication.
How cells read the genome from DNA to protein Notes
The document summarizes the process of transcription and translation in cells. It describes:
1) Transcription of DNA to RNA which is catalyzed by RNA polymerase and involves the formation of RNA through the addition of ribonucleotides.
2) Processing of eukaryotic pre-mRNA which involves capping, splicing, and polyadenylation to form mature mRNA.
3) Translation of mRNA to protein which occurs on ribosomes and involves tRNAs carrying amino acids that are linked together through peptide bond formation catalyzed by the ribosome. Accuracy is ensured by induced fit binding and kinetic proofreading.
Transcription in prokaryotes
The document summarizes transcription in prokaryotes. It discusses that transcription is carried out by RNA polymerase, which copies DNA into RNA. In prokaryotes, a single RNA polymerase enzyme governs transcription. It consists of core subunits and a sigma factor that helps recognize promoter regions on DNA. Transcription occurs in three steps - initiation, elongation, and termination. Initiation involves the RNA polymerase binding to promoter sites on DNA. Elongation extends the RNA chain. Termination ends transcription as the RNA and polymerase dissociate via either rho-dependent or rho-independent mechanisms.
TRANSCRIPTION & POST-TRANSCRIPTIONAL MODIFICATIONS
Transcription is the process of synthesizing RNA from a DNA template. In prokaryotes, a single RNA polymerase synthesizes all RNA, while eukaryotes have multiple RNA polymerases. The enzyme binds to promoter regions on DNA and uses one strand as a template to make complementary RNA. Primary transcripts in eukaryotes undergo processing like capping, polyadenylation, and splicing to produce mature, functional RNAs that can be translated or act as non-coding RNAs. Transcription involves initiation, elongation, and termination and can be inhibited by various antibiotics that target bacterial or eukaryotic RNA polymerases.
Transcription in eukaryotes
transcription process in eukaryotes their factors RNA polymerase enzyme an intiation elongation termination process
DNA Replication -
1. DNA replication begins with the unwinding of the DNA double helix by the helicase enzyme. This exposes the two strands of DNA to serve as templates for DNA synthesis.
2. RNA primers are synthesized by the primase enzyme and DNA polymerase adds complementary nucleotides to the 3' end of each primer, elongating it into DNA.
3. The leading strand is synthesized continuously in the 5' to 3' direction while the lagging strand is synthesized in fragments called Okazaki fragments which are later joined by DNA ligase.
4. Several enzymes are involved including DNA polymerase, ligase, helicase, topoisomerase and others to accurately and efficiently copy DNA. DNA replication ensures faithful transmission of
Exonucleases & endonucleases as molecular tools
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Dna replication in eukaryotes
This document describes the process of DNA replication in eukaryotes. It occurs in S phase of the cell cycle and involves three main stages: initiation, formation of the initiation complex, and elongation. Initiation requires the assembly of pre-replication complexes containing ORC, Cdc6, Cdt1 and MCM proteins. In S phase, Cdc45 and GINS are recruited to form the initiation complex. Elongation proceeds bidirectionally from replication forks, with leading strand synthesis continuous and lagging strand discontinuous via Okazaki fragments. Replication terminates at telomeres.
DNA replication in prokaryotes
The document summarizes the process of DNA replication in prokaryotic cells like E. coli. It describes the three main stages: initiation at the Ori C origin site involving DnaA and DnaB proteins, elongation where the leading strand is synthesized continuously and the lagging strand requires RNA primers, and termination when the replication forks meet specific termination sites and DnaB is released. DNA replication allows faithful copying of the parental DNA to produce two identical progeny DNA molecules.
Prokaryotic translation
It is the process of synthesis of protein by encoding information on mRNA.
Protein synthesis requires mRNA, tRNA, aminoacids, ribosome and enzyme aminoacyl tRNA synthase
PROKARYOTIC DNA REPLICATION PRESENTATION
Prokaryotic DNA replication occurs through a semiconservative process involving three main steps: initiation, elongation, and termination. Initiation begins with unwinding of the DNA at the origin of replication by helicase. Elongation then takes place as DNA polymerase adds nucleotides to form new strands, with leading strand synthesis occurring continuously and lagging strand in fragments. Termination occurs when the replication forks from opposite directions meet and are halted by tus-ter complexes, separating the duplicated chromosomes.
DNA replication in eukaryotes
DNA replication is the process by which a cell makes an identical copy of its DNA. It occurs in three main steps: initiation, elongation, and termination. Initiation begins at origins of replication and involves unwinding of the DNA double helix by helicases. During elongation, DNA polymerases add nucleotides to build new strands based on the existing DNA templates. Termination occurs when the replication forks meet at the end of the DNA molecule. DNA replication is semi-conservative, meaning each new DNA molecule contains one original and one new strand of DNA.
Eukaryotic transcription
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Histidine operon
The document summarizes the histidine operon and its regulation in the bacterium Salmonella typhimurium. The histidine operon contains 9 structural genes that are transcribed into a single mRNA. It is regulated by both feedback inhibition and attenuation control. In feedback inhibition, high intracellular histidine levels lead to feedback inhibition of the biosynthetic pathway. In attenuation control, the level of charged histidyl-tRNA determines whether transcription terminates or the structural genes are expressed. When histidyl-tRNA levels are high, transcription terminates. When levels are low, the ribosome pauses and anti-termination occurs, allowing expression of the structural genes.
Dna replication in eukaryotes
DNA replication in eukaryotes occurs in the nucleus and proceeds in the 5' to 3' direction. It involves several enzymes including helicase, which opens the DNA helix, and DNA polymerase epsilon and delta, which synthesize the leading and lagging strands respectively. Replication occurs through initiation, elongation, and termination steps. At the origin of replication, a pre-replication complex forms and the replication fork bubbles outwards. RNA primers are laid down and DNA synthesis occurs continuously on the leading strand but discontinuously on the lagging strand. The primers are later removed and the gaps filled in.
DNA replication
This document summarizes DNA replication. It discusses that DNA replication is the process where a cell makes an identical copy of its DNA before cell division. This involves unwinding the DNA double helix, forming new strands to complement each original strand, and using enzymes like DNA polymerase and helicase. Replication occurs differently in prokaryotes and eukaryotes and results in two identical copies of DNA for the daughter cells.
Tendances (20)
DNA transcription & Post Transcriptional Modification
DNA transcription & Post Transcriptional Modification
How cells read the genome from DNA to protein Notes
How cells read the genome from DNA to protein Notes
TRANSCRIPTION & POST-TRANSCRIPTIONAL MODIFICATIONS
TRANSCRIPTION & POST-TRANSCRIPTIONAL MODIFICATIONS
Similaire à prokaryotic transcription.pptx
PROKAYOTIC TRANSCRIPTION.pptx
Transcription in prokaryotes involves RNA polymerase copying a portion of the DNA genome into RNA. It occurs in three main steps: initiation, elongation, and termination. Initiation begins with RNA polymerase binding to promoter sequences on DNA to form a closed complex, then an open complex. Elongation entails RNA polymerase continuing to synthesize RNA down the DNA template. Termination can occur via either rho-independent or rho-dependent mechanisms, stopping further RNA production.
transcription in prokaryotes and RNA polymerase of prokaryotes
The core RNA polymerase associates with the sigma factor to generate the RNA polymerase holoenzyme, which is required for recruiting RNA polymerase to the promoter. The sigma factor binds to the -10 and -35 promoter elements. During transcription initiation, RNA polymerase unwinds the DNA and begins RNA synthesis. It then enters elongation, synthesizing RNA processively until it reaches a terminator sequence and dissociates from the DNA. RNA polymerase synthesizes various RNA transcripts including mRNA, tRNA, and rRNA.
Transcription
description of mechanism of transcription in prokaryotes and eukaryotes with clear explanation and clear pictures and also mentiong of different promotors and enhancers and silencers
RNA Synthesis (Transcription).pptx
RNA is synthesized through a process called transcription. During transcription, RNA polymerase binds to a gene's promoter and copies the gene sequence into RNA. The RNA transcript is then processed through splicing, capping, polyadenylation, and other modifications before being used to produce proteins. Key steps in transcription include initiation at the promoter, elongation as RNA polymerase moves along the DNA, and termination once the full sequence has been copied.
Transcription in prokaryotes:mRNA,rRNA and tRNA transcription.
This ppt tells you about the details of transcription in prokaryotes; the initiation, elongation and the termination steps. It not only covers the mRNA transcription, but also the rRNA and tRNA transcription.
Transcription in prokaryotes
This document discusses the central dogma of biology and the process of transcription. It describes the three main steps of transcription - initiation, elongation, and termination. Initiation involves the RNA polymerase binding to the promoter sequence on DNA and separating the DNA strands to form an open complex. Elongation is the addition of nucleotides to synthesize RNA. Termination can occur via either Rho-independent or Rho-dependent mechanisms, with the former utilizing a terminator sequence and hairpin structure in the RNA and the latter involving the Rho protein.
Prokaryotic transcription
Prokaryotes are organisms that consist of a single prokaryotic cell. Eukaryotic cells are found in plants, animals, fungi, and protists. They range from 10–100 μm in diameter, and their DNA is contained within a membrane-bound nucleus.Prokaryotes do not have membrane-enclosed nuclei. Therefore, the processes of transcription, translation, and mRNA degradation can all occur simultaneously.
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GENE EXPRESSION AND IT’S REGULATION.pptx
Gene expression is the process by which information from a gene is used to direct protein synthesis. It involves replication, transcription, and translation. Regulation of gene expression controls the amount and timing of gene products. Regulation occurs through transcription factors binding to regulatory elements near gene promoters to turn genes on and off. This precise control of gene expression is vital for cellular differentiation and adaptation.
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Eukaryotic transcription
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Transcription
Transcription is the process by which RNA is synthesized from a DNA template by RNA polymerase. It involves initiation at a promoter region, elongation as nucleotides are added to the growing RNA strand, and termination. While similar to DNA replication, transcription only uses one DNA strand as a template and does not require primers.
Transcription BIOLOVE ed. 1
RNA polymerase carries out transcription by linking ribonucleotides to form RNA molecules using DNA as a template. Transcription initiates in both prokaryotic and eukaryotic cells and proceeds more slowly than DNA replication. In bacteria, transcription involves three main steps - initiation at promoter sequences, elongation as RNA polymerase moves along DNA, and termination. RNA polymerase requires sigma factors to bind promoters and initiate transcription accurately.
Basic principle of transcription, organization of transcriptional units in pr...
Transcription is the first step of gene expression where DNA is copied into RNA. In prokaryotes, there are three main components of the transcriptional unit: 1) Promoters located upstream of genes that are recognized by RNA polymerase to initiate transcription, 2) The RNA coding sequence which is the DNA region that is transcribed, and 3) Terminators which allow transcription to stop and release the RNA transcript. Promoters contain -10 and -35 sequences that recruit RNA polymerase. Termination can occur via Rho-dependent or Rho-independent mechanisms involving RNA secondary structure formation and polymerase stalling.
Transcription.ppt
Transcription is the process by which RNA polymerase converts DNA into RNA. It involves 3 stages: initiation, elongation, and termination. Initiation begins at promoter sequences on DNA and requires a sigma factor. During elongation, RNA polymerase proofreads as it synthesizes RNA to ensure accuracy. Termination occurs when the polymerase reaches termination sequences and releases the RNA transcript.
Transcription.ppt
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– chlorophyll absorbs
energy from sunlight
– energized electrons
enter electron
transport chain
– water molecules are
split
– oxygen is released as
waste
– hydrogen ions are
transported across
thylakoid membrane
4.1 Chemical Energy and ATP
• Photosystem I captures energy and produces energycarrying molecules.
– chlorophyll absorbs
energy from sunlight
– energized electrons
are used to make
NADPH
– NADPH is transferred
to light-independent
reactions
4.1 Chemical Energy and ATP
• The light-dependent reactions produce ATP.
– hydrogen ions flow through a channel in the thylakoid
membrane
– ATP synthase attached to the channel makes ATP
4.1 Chemical Energy and ATP
• Light-independent
reactions occur in the
stroma and use CO2
molecules.
The second stage of photosynthesis uses energy from
the first stage to make sugars.
4.1 Chemical Energy and ATP
• A molecule of glucose is formed as it stores some of the
energy captured from sunlight.
– carbon dioxide molecules enter the Calvin Photosystem II captures and transfers energy.
– chlorophyll absorbs
energy from sunlight
– energized electrons
enter electron
transport chain
– water molecules are
split
– oxygen is released as
waste
– hydrogen ions are
transported across
thylakoid membrane
4.1 Chemical Energy and ATP
• Photosystem I captures energy and produces energycarrying molecules.
– chlorophyll absorbs
energy from sunlight
– energized electrons
are used to make
NADPH
– NADPH is transferred
to light-independent
reactions
4.1 Chemical Energy and ATP
• The light-dependent reactions produce ATP.
– hydrogen ions flow through a channel in the thylakoid
membrane
– ATP synthase attached to the channel makes ATP
4.1 Chemical Energy and ATP
• Light-independent
reactions occur in the
stroma and use CO2
molecules.
The second stage of photosynthesis uses energy from
the first stage to make sugars.
4.1 Chemical Energy and ATP
• A molecule of glucose is formed as it stores some of the
energy captured from sunlight.
– carbon dioxide molecules enter the Calvin Photosystem II captures and transfers energy.
– chlorophyll absorbs
energy from sunlight
– energized electrons
enter electron
transport chain
– water molecules are
split
– oxygen is released as
waste
– hydrogen ions are
transported across
thylakoid membrane
4.1 Chemical Energy and ATP
• Photosystem I captures energy and produces energycarrying molecules.
– chlorophyll absorbs
energy from sunlight
– energized electrons
are used to make
NADPH
– NADPH is transferred
to light-independent
reactions
4.1 Chemical Energy and ATP
• The light-dependent reactions produce ATP.
– hydrogen ions flow through a channel in the thylakoid
membrane
– ATP synthase attached to the channel makes ATP
4.1 Chemical Energy and ATP
• Light-independent
reactions occur in the
stroma and use CO2
molecules.
The second stage of photosynthesis uses energy frvf
EUKARYOTIC TRANSCRIPTION.pptx
Eukaryotic transcription involves RNA polymerase enzymes transcribing DNA into RNA. It occurs within the nucleus and involves three main steps: initiation, elongation, and termination. Initiation is more complex in eukaryotes and involves recruitment of transcription factors to promoter regions. Elongation utilizes RNA polymerase to synthesize RNA using DNA as a template. Termination does not rely on stem-loop structures as in prokaryotes. The primary transcript then undergoes processing before becoming a mature, functional RNA molecule.
1123
This document summarizes transcription in prokaryotes and eukaryotes. It discusses the RNA polymerase, promoters, initiation, elongation and termination processes. In prokaryotes, RNA polymerase recognizes promoter sequences and initiates transcription. Elongation continually adds nucleotides to form mRNA. Termination occurs via rho-dependent or independent mechanisms. Eukaryotic transcription involves RNA polymerases and additional regulatory elements. It produces pre-mRNA which undergoes processing and modifications before translation.
Unit 7 prok transcription
Prokaryotic transcription involves RNA polymerases catalyzing the synthesis of RNA molecules using a DNA template. There are three main steps: initiation, elongation, and termination. Initiation begins with the binding of RNA polymerase to promoter regions on the DNA. Elongation then occurs as the polymerase unwinds the DNA and adds nucleotides to the growing RNA chain. Termination happens when either Rho-dependent or Rho-independent termination signals are reached, causing the release of the completed RNA molecule.
Transcription (term paper) by Ganesh M
Transcription is the process by which RNA is synthesized from a DNA template. It involves three main steps - initiation, elongation, and termination. In prokaryotes, RNA polymerase binds directly to the promoter region of DNA and initiates transcription. Eukaryotes require various transcription factors to help RNA polymerase bind to the promoter. The transcription process is similar between prokaryotes and eukaryotes, but eukaryotes have three types of RNA polymerase and more complex regulation. Reverse transcription is the process by which DNA is synthesized from an RNA template using the enzyme reverse transcriptase.
Similaire à prokaryotic transcription.pptx (20)
transcription in prokaryotes and RNA polymerase of prokaryotes
transcription in prokaryotes and RNA polymerase of prokaryotes
Transcription in prokaryotes:mRNA,rRNA and tRNA transcription.
Transcription in prokaryotes:mRNA,rRNA and tRNA transcription.
Basic principle of transcription, organization of transcriptional units in pr...
Basic principle of transcription, organization of transcriptional units in pr...
Dernier
The debris of the ‘last major merger’ is dynamically young
The Milky Way’s (MW) inner stellar halo contains an [Fe/H]-rich component with highly eccentric orbits, often referred to as the
‘last major merger.’ Hypotheses for the origin of this component include Gaia-Sausage/Enceladus (GSE), where the progenitor
collided with the MW proto-disc 8–11 Gyr ago, and the Virgo Radial Merger (VRM), where the progenitor collided with the
MW disc within the last 3 Gyr. These two scenarios make different predictions about observable structure in local phase space,
because the morphology of debris depends on how long it has had to phase mix. The recently identified phase-space folds in Gaia
DR3 have positive caustic velocities, making them fundamentally different than the phase-mixed chevrons found in simulations
at late times. Roughly 20 per cent of the stars in the prograde local stellar halo are associated with the observed caustics. Based
on a simple phase-mixing model, the observed number of caustics are consistent with a merger that occurred 1–2 Gyr ago.
We also compare the observed phase-space distribution to FIRE-2 Latte simulations of GSE-like mergers, using a quantitative
measurement of phase mixing (2D causticality). The observed local phase-space distribution best matches the simulated data
1–2 Gyr after collision, and certainly not later than 3 Gyr. This is further evidence that the progenitor of the ‘last major merger’
did not collide with the MW proto-disc at early times, as is thought for the GSE, but instead collided with the MW disc within
the last few Gyr, consistent with the body of work surrounding the VRM.
The cost of acquiring information by natural selection
This is a short talk that I gave at the Banff International Research Station workshop on Modeling and Theory in Population Biology. The idea is to try to understand how the burden of natural selection relates to the amount of information that selection puts into the genome.
It's based on the first part of this research paper:
The cost of information acquisition by natural selection
Ryan Seamus McGee, Olivia Kosterlitz, Artem Kaznatcheev, Benjamin Kerr, Carl T. Bergstrom
bioRxiv 2022.07.02.498577; doi: https://doi.org/10.1101/2022.07.02.498577
Pests of Storage_Identification_Dr.UPR.pdf
InIndia-post-harvestlosses-unscientificstorage,insects,rodents,micro-organismsetc.,accountforabout10percentoftotalfoodgrains
Graininfestation
Directdamage
Indirectly
•theexuviae,skin,deadinsects
•theirexcretawhichmakefoodunfitforhumanconsumption
About600speciesofinsectshavebeenassociatedwithstoredgrainproducts
100speciesofinsectpestsofstoredproductscauseeconomiclosses
Sharlene Leurig - Enabling Onsite Water Use with Net Zero Water
Sharlene Leurig - Enabling Onsite Water Use with Net Zero WaterTexas Alliance of Groundwater Districts
Presented at June 6-7 Texas Alliance of Groundwater Districts Business Meetingwaterlessdyeingtechnolgyusing carbon dioxide chemicalspdf
The technology uses reclaimed CO₂ as the dyeing medium in a closed loop process. When pressurized, CO₂ becomes supercritical (SC-CO₂). In this state CO₂ has a very high solvent power, allowing the dye to dissolve easily.
Applied Science: Thermodynamics, Laws & Methodology.pdf
When I was asked to give a companion lecture in support of ‘The Philosophy of Science’ (https://shorturl.at/4pUXz) I decided not to walk through the detail of the many methodologies in order of use. Instead, I chose to employ a long standing, and ongoing, scientific development as an exemplar. And so, I chose the ever evolving story of Thermodynamics as a scientific investigation at its best.
Conducted over a period of >200 years, Thermodynamics R&D, and application, benefitted from the highest levels of professionalism, collaboration, and technical thoroughness. New layers of application, methodology, and practice were made possible by the progressive advance of technology. In turn, this has seen measurement and modelling accuracy continually improved at a micro and macro level.
Perhaps most importantly, Thermodynamics rapidly became a primary tool in the advance of applied science/engineering/technology, spanning micro-tech, to aerospace and cosmology. I can think of no better a story to illustrate the breadth of scientific methodologies and applications at their best.
ESR spectroscopy in liquid food and beverages.pptx
With increasing population, people need to rely on packaged food stuffs. Packaging of food materials requires the preservation of food. There are various methods for the treatment of food to preserve them and irradiation treatment of food is one of them. It is the most common and the most harmless method for the food preservation as it does not alter the necessary micronutrients of food materials. Although irradiated food doesn’t cause any harm to the human health but still the quality assessment of food is required to provide consumers with necessary information about the food. ESR spectroscopy is the most sophisticated way to investigate the quality of the food and the free radicals induced during the processing of the food. ESR spin trapping technique is useful for the detection of highly unstable radicals in the food. The antioxidant capability of liquid food and beverages in mainly performed by spin trapping technique.
20240520 Planning a Circuit Simulator in JavaScript.pptx
Evaporation step counter work. I have done a physical experiment.
(Work in progress.)
Bob Reedy - Nitrate in Texas Groundwater.pdf
Presented at June 6-7 Texas Alliance of Groundwater Districts Business Meeting
Randomised Optimisation Algorithms in DAPHNE
Slides from talk:
Aleš Zamuda: Randomised Optimisation Algorithms in DAPHNE .
Austrian-Slovenian HPC Meeting 2024 – ASHPC24, Seeblickhotel Grundlsee in Austria, 10–13 June 2024
https://ashpc.eu/
Mending Clothing to Support Sustainable Fashion_CIMaR 2024.pdf
Ozturkcan, S., Berndt, A., & Angelakis, A. (2024). Mending clothing to support sustainable fashion. Presented at the 31st Annual Conference by the Consortium for International Marketing Research (CIMaR), 10-13 Jun 2024, University of Gävle, Sweden.
8.Isolation of pure cultures and preservation of cultures.pdf
Isolation of pure culture, its various method.
Micronuclei test.M.sc.zoology.fisheries.
Current Ms word generated power point presentation covers major details about the micronuclei test. It's significance and assays to conduct it. It is used to detect the micronuclei formation inside the cells of nearly every multicellular organism. It's formation takes place during chromosomal sepration at metaphase.
Describing and Interpreting an Immersive Learning Case with the Immersion Cub...
Current descriptions of immersive learning cases are often difficult or impossible to compare. This is due to a myriad of different options on what details to include, which aspects are relevant, and on the descriptive approaches employed. Also, these aspects often combine very specific details with more general guidelines or indicate intents and rationales without clarifying their implementation. In this paper we provide a method to describe immersive learning cases that is structured to enable comparisons, yet flexible enough to allow researchers and practitioners to decide which aspects to include. This method leverages a taxonomy that classifies educational aspects at three levels (uses, practices, and strategies) and then utilizes two frameworks, the Immersive Learning Brain and the Immersion Cube, to enable a structured description and interpretation of immersive learning cases. The method is then demonstrated on a published immersive learning case on training for wind turbine maintenance using virtual reality. Applying the method results in a structured artifact, the Immersive Learning Case Sheet, that tags the case with its proximal uses, practices, and strategies, and refines the free text case description to ensure that matching details are included. This contribution is thus a case description method in support of future comparative research of immersive learning cases. We then discuss how the resulting description and interpretation can be leveraged to change immersion learning cases, by enriching them (considering low-effort changes or additions) or innovating (exploring more challenging avenues of transformation). The method holds significant promise to support better-grounded research in immersive learning.
Shallowest Oil Discovery of Turkiye.pptx
The Petroleum System of the Çukurova Field - the Shallowest Oil Discovery of Türkiye, Adana
11.1 Role of physical biological in deterioration of grains.pdf
Storagedeteriorationisanyformoflossinquantityandqualityofbio-materials.
Themajorcausesofdeteriorationinstorage
•Physical
•Biological
•Mechanical
•Chemical
Storageonlypreservesquality.Itneverimprovesquality.
Itisadvisabletostartstoragewithqualityfoodproduct.Productwithinitialpoorqualityquicklydepreciates
EWOCS-I: The catalog of X-ray sources in Westerlund 1 from the Extended Weste...
Context. With a mass exceeding several 104 M⊙ and a rich and dense population of massive stars, supermassive young star clusters
represent the most massive star-forming environment that is dominated by the feedback from massive stars and gravitational interactions
among stars.
Aims. In this paper we present the Extended Westerlund 1 and 2 Open Clusters Survey (EWOCS) project, which aims to investigate
the influence of the starburst environment on the formation of stars and planets, and on the evolution of both low and high mass stars.
The primary targets of this project are Westerlund 1 and 2, the closest supermassive star clusters to the Sun.
Methods. The project is based primarily on recent observations conducted with the Chandra and JWST observatories. Specifically,
the Chandra survey of Westerlund 1 consists of 36 new ACIS-I observations, nearly co-pointed, for a total exposure time of 1 Msec.
Additionally, we included 8 archival Chandra/ACIS-S observations. This paper presents the resulting catalog of X-ray sources within
and around Westerlund 1. Sources were detected by combining various existing methods, and photon extraction and source validation
were carried out using the ACIS-Extract software.
Results. The EWOCS X-ray catalog comprises 5963 validated sources out of the 9420 initially provided to ACIS-Extract, reaching a
photon flux threshold of approximately 2 × 10−8 photons cm−2
s
−1
. The X-ray sources exhibit a highly concentrated spatial distribution,
with 1075 sources located within the central 1 arcmin. We have successfully detected X-ray emissions from 126 out of the 166 known
massive stars of the cluster, and we have collected over 71 000 photons from the magnetar CXO J164710.20-455217.
快速办理(UAM毕业证书)马德里自治大学毕业证学位证一模一样
学校原件一模一样【微信:741003700 】《(UAM毕业证书)马德里自治大学毕业证学位证》【微信:741003700 】学位证,留信认证(真实可查,永久存档)原件一模一样纸张工艺/offer、雅思、外壳等材料/诚信可靠,可直接看成品样本,帮您解决无法毕业带来的各种难题!外壳,原版制作,诚信可靠,可直接看成品样本。行业标杆!精益求精,诚心合作,真诚制作!多年品质 ,按需精细制作,24小时接单,全套进口原装设备。十五年致力于帮助留学生解决难题,包您满意。
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◇面对父母的压力,希望尽快拿到;
◇不清楚认证流程以及材料该如何准备;
◇回国时间很长,忘记办理;
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◇企事业单位必须要求办理的
◇需要报考公务员、购买免税车、落转户口
◇申请留学生创业基金
留信网认证的作用:
1:该专业认证可证明留学生真实身份
2:同时对留学生所学专业登记给予评定
3:国家专业人才认证中心颁发入库证书
4:这个认证书并且可以归档倒地方
5:凡事获得留信网入网的信息将会逐步更新到个人身份内,将在公安局网内查询个人身份证信息后,同步读取人才网入库信息
6:个人职称评审加20分
7:个人信誉贷款加10分
8:在国家人才网主办的国家网络招聘大会中纳入资料,供国家高端企业选择人才
Dernier (20)
The debris of the ‘last major merger’ is dynamically young
The debris of the ‘last major merger’ is dynamically young
The cost of acquiring information by natural selection
The cost of acquiring information by natural selection
Sharlene Leurig - Enabling Onsite Water Use with Net Zero Water
Sharlene Leurig - Enabling Onsite Water Use with Net Zero Water
waterlessdyeingtechnolgyusing carbon dioxide chemicalspdf
waterlessdyeingtechnolgyusing carbon dioxide chemicalspdf
Basics of crystallography, crystal systems, classes and different forms
Basics of crystallography, crystal systems, classes and different forms
Applied Science: Thermodynamics, Laws & Methodology.pdf
Applied Science: Thermodynamics, Laws & Methodology.pdf
ESR spectroscopy in liquid food and beverages.pptx
ESR spectroscopy in liquid food and beverages.pptx
20240520 Planning a Circuit Simulator in JavaScript.pptx
20240520 Planning a Circuit Simulator in JavaScript.pptx
Mending Clothing to Support Sustainable Fashion_CIMaR 2024.pdf
Mending Clothing to Support Sustainable Fashion_CIMaR 2024.pdf
8.Isolation of pure cultures and preservation of cultures.pdf
8.Isolation of pure cultures and preservation of cultures.pdf
Describing and Interpreting an Immersive Learning Case with the Immersion Cub...
Describing and Interpreting an Immersive Learning Case with the Immersion Cub...
11.1 Role of physical biological in deterioration of grains.pdf
11.1 Role of physical biological in deterioration of grains.pdf
EWOCS-I: The catalog of X-ray sources in Westerlund 1 from the Extended Weste...
EWOCS-I: The catalog of X-ray sources in Westerlund 1 from the Extended Weste...
prokaryotic transcription.pptx
- 2. The process of synthesis of RNA by coping the template strand of DNA is called transcription Transcription is enzymatically similar to DNA replication Both process involve enzyme that synthesis new strands of nucleic acid complementary to the DNA strand. Major difference is that IN DNA replication DNA polymerase add deoxyribonucleic acid to the template DNA. But in transcription RNA polymerase add ribonucleic acid to the template DNA.
- 3. RNA POLYMERASE ENZYME •RNA polymerase enzyme has five subunits. • Two alpha ( α ) subunit • Betta( β )subunit • A betta prime (β’) subunit •A small omega (Ѡ) subunit Core enzyme form RNA polymerase cannot start transcription by its own it need a factor called sigma factor. It is a protein that allows specific binding of RNA polymerase to promoter. RNA Polymerase core with this sigma factor is called holoenzyme So complete RNA polymerase holoenzyme has 6 subunit.
- 4. PROMOTER REGION It have RNA start point where the transcription starts, That is the +1 position. It have -10 region called the PRIBNOW BOX followed by -35 region. -10 region has sequence TATAAT And -35 region has TTGACA sequence. In these regions the RNA POLYMERASE enzyme binds -10 region has the function of transcription initiation
- 6. INITIATION 1. FORMATION OF CLOSED COMPLEX RNA polymerase enzyme bind to the promoter region. DNA at this stage will be double stranded. This complex is called the closed complex 2. FORMATION OF OPEN COMPLEX DNA strand at the transcription start site unwind to form an open complex. When open complex are formed the enzyme starts to add ribonucleotides ( rNTP’s) on the template DNA. unlike DNA polymerase, RNA polymerase do not need a primer to initiate transcription.
- 7. 3. ABORTIVE INITIATION When the enzyme synthesize short RNA molecule less than 10 base pair , it does not further elongates which is called as abortive initiation. When the RNA Polymerase stabilizes became able to copy 10 nucleotide or more that will be called as successive initiation. From here the elongation starts.
- 8. ELONGATION When sigma factor is released RNA POLYMERASE proceeds the process of elongation. The dissociation of sigma factor allows the core polymerase enzyme to proceed along the DNA template synthesising mRNA in the 5’ to 3’ direction at a rate of 40 nucleotide per second.
- 9. TERMINATION When polymerase transcribe the gene it must release the transcribed product this process is called termination Termination takes place in two modes Rho independent Rho dependent
- 10. RHO INDEPENDENT •In rho independent termination no external protein or external factor are required for termination. •Rho independent terminator also known as intrinsic terminator. •It consist of 2 sequence elements. Short inverted repeats of 2 nucleotides followed by 8 A : T Rich regions. •RNA transcribe inverted repeated sequence and the resulting RNA form a hairpin like structure by base pairing with itself. •The hairpin thus formed halt the RNA polymerase enzyme.
- 11. RHO INDEPENDENT The inverted repeats is further followed by AT rich sequence AT rich sequence after transcription forms the new AU Base pair the weakest of all the base pair. Because of this the RNA Is finally releases ending the transcription
- 12. RHO DEPENDANT It depends on protein called rho factor. The rho protein bind to single stranded RNA Rich in cytosine residues . These cytosine residues are also known as rho utilization site . When RNA polymerase reaches 100 nucleotide away from the right side it stops the transcription .