1. DNA replication is the process by which a double-stranded DNA molecule is copied to produce two identical DNA molecules, and it is essential for cell division.
2. In eukaryotes, initiation of DNA replication begins in G1 phase with formation of the pre-replication complex, and continues into S phase when the MCM helicase is activated and unwinds DNA.
3. The cell cycle is composed of interphase, which includes G1, S, and G2 phases for cell growth and DNA replication, and the M phase for nuclear and cell division. Initiation of eukaryotic DNA replication bridges the G1 and S phases of the cell cycle.
Definition - Rolling circle replication is a process of unidirectional nucleic acid replication.
* can rapidly synthesize multiple copies of circular molecules of DNA or RNA, such as plasmids.
* Eucaryotic also replicate.
* widely used in molecular biology & biomedical
nanotechnology, especially in the field of
biosensing (as a method of signal Amplification).
Steps:
Circular ds DNA will be “nicked”
3` end is elongated →Leading strand
5` end displaced → Lagging strand
made up of double stranded by OKAZAKI fragments.
4) Replication of both “ unnicked” and displaced ss DNA
5) Displaced DNA circulates and synthesis its own complementary strand.
Initation-- phosphate ends, by the action of:
a) Helicase
b) Topoisomerases
c) Single stranded binding proteins(SSBPs)
Elongation-OH group of broken strand, using the unbroken strand as a template. The polymerase will start to move in a circle for elongation, due to which it is named as Rolling Circle Model.
end will be displaced and will grow out like a waving thread.
Termination-* At the point of termination, the linear DNA molecule is cleaved from the circle resulting in a double stranded circular DNA molecule and a single- stranded linear DNA molecule.
* The linear single stranded molecule is circularized by the action of ligase and then replication to double stranded circular plasmid molecule.
Example- Conjugation of F+ and F- bacteria
Diagrammatic representation of Rolling circle
some Examples-Viral DNA
* Human herpes virus
* Human papilloma virus
* Geminivirus
Viral RNA
* pospiviridiae
* Avsunviridiae
Reference:- https://en. m. wikipedia.org
what- when- how.com
https//www.sciencedirect.com
www.slideshare.com
Genetics-notes.wikispace.com
you tube
Prescott 5th edition page.no: 236, 237
Brock biology of microorganism , page.no: 253,616
Definition - Rolling circle replication is a process of unidirectional nucleic acid replication.
* can rapidly synthesize multiple copies of circular molecules of DNA or RNA, such as plasmids.
* Eucaryotic also replicate.
* widely used in molecular biology & biomedical
nanotechnology, especially in the field of
biosensing (as a method of signal Amplification).
Steps:
Circular ds DNA will be “nicked”
3` end is elongated →Leading strand
5` end displaced → Lagging strand
made up of double stranded by OKAZAKI fragments.
4) Replication of both “ unnicked” and displaced ss DNA
5) Displaced DNA circulates and synthesis its own complementary strand.
Initation-- phosphate ends, by the action of:
a) Helicase
b) Topoisomerases
c) Single stranded binding proteins(SSBPs)
Elongation-OH group of broken strand, using the unbroken strand as a template. The polymerase will start to move in a circle for elongation, due to which it is named as Rolling Circle Model.
end will be displaced and will grow out like a waving thread.
Termination-* At the point of termination, the linear DNA molecule is cleaved from the circle resulting in a double stranded circular DNA molecule and a single- stranded linear DNA molecule.
* The linear single stranded molecule is circularized by the action of ligase and then replication to double stranded circular plasmid molecule.
Example- Conjugation of F+ and F- bacteria
Diagrammatic representation of Rolling circle
some Examples-Viral DNA
* Human herpes virus
* Human papilloma virus
* Geminivirus
Viral RNA
* pospiviridiae
* Avsunviridiae
Reference:- https://en. m. wikipedia.org
what- when- how.com
https//www.sciencedirect.com
www.slideshare.com
Genetics-notes.wikispace.com
you tube
Prescott 5th edition page.no: 236, 237
Brock biology of microorganism , page.no: 253,616
control of gene expression by sigma factor and post transcriptional controlIndrajaDoradla
explanation of control of gene expression by sigma factor and decription of sigma factor and detailed explation of post transcriptional control by antisense technology and rna i
Comparison between Replication of Prokaryotes and Eukaryotes mujahid hussain
Comparison between Replication of Prokaryotes and Eukaryotes
Mujahid Hussain
(M.Phil Botany)
Department of Botany
University of Sargodha, Sargodha ,Punjab, Pakistan
DNA as a Genetic Material - Dr. P. Saranraj, Assistant Professor, Department of Microbiology, Sacred Heart College (Autonomous), Tirupattur, Vellore District, Tamil Nadu, India.
control of gene expression by sigma factor and post transcriptional controlIndrajaDoradla
explanation of control of gene expression by sigma factor and decription of sigma factor and detailed explation of post transcriptional control by antisense technology and rna i
Comparison between Replication of Prokaryotes and Eukaryotes mujahid hussain
Comparison between Replication of Prokaryotes and Eukaryotes
Mujahid Hussain
(M.Phil Botany)
Department of Botany
University of Sargodha, Sargodha ,Punjab, Pakistan
DNA as a Genetic Material - Dr. P. Saranraj, Assistant Professor, Department of Microbiology, Sacred Heart College (Autonomous), Tirupattur, Vellore District, Tamil Nadu, India.
Cell cycle and Regulation
* cell Division is occur in every human but these have certaint check point to preventing from the forming the defective cell or cancerious cell.
This presentation on "Cell Cycle regulation" takes you to the cell cycle describing the stages and checkpoints involved providing some of the evidences of cell cycle regulation. Then we will move to cyclins and cyclin dependent kinases and the mechanism they follow.
This journey in regulation of cell cycle will take a halt after a general discussion of positive and negative cell cycle regulators.
Thankyou.
This presentation on "Cell Cycle regulation" takes you to the cell cycle describing the stages and checkpoints involved providing some of the evidences of cell cycle regulation. Then we will move to cyclins and cyclin dependent kinases and the mechanism they follow.
This journey in regulation of cell cycle will take a halt after a general discussion of positive and negative cell cycle regulators.
Thankyou.
Why do different cell types' rates of the cell cycle differ?
The cell cycle is swiftly completed by injured or lost cell types to produce replacements.
Adult skin and digestive tract cells go through the cell cycle quite fast, whereas nervous system cells divide very seldom.
Cells divide regularly during embryonic development, perhaps as frequently as once or twice an hour, moving through the cell cycle very quickly.
What is the cell cycle?
The regular sequence of activities that cells go through as they develop and divide is known as the cell cycle. Prokaryotic cells go through a rapid cycle of cell division, DNA replication, and expansion. In prokaryotes, cell division occurs in a single stage known as binary fission (shown right).Compared to prokaryotic cells, eukaryotic cells have a more complicated cell cycle.
How is the eukaryotic cell cycle divided?
Interphase is the period between cell divisions. Depending on the kind of cell, the interphase might be shorter or longer.
The three stages or phases of the eukaryotic interphase are G1, S, and G2.
The M phase of the cell cycle is when eukaryotic cells divide. Mitosis and cytokinesis are the two stages that make up the M phase.
What happens during each phase of eukaryotic interphase?
G1: Cells do most of their growing during this phase. It begins when mitosis is complete and ends when DNA replication begins.
S: DNA is synthesized as chromosomes are replicated.
G2: Many of the molecules and cell structures required for cell division are produced; usually the shortest phase of the cell cycle.
What happens during the M phase of the eukaryotic cell cycle?
The M phase is usually much shorter than interphase and results in two daughter cells.
The first step of the M phase is mitosis. The cell’s nucleus divides during mitosis.
The second step of the M phase is cytokinesis, during which the cell’s cytoplasm is divided.
What are the steps of mitosis?
Mitosis consists of four steps: prophase, metaphase, anaphase, and telophase.
Prophase: nuclear envelope breaks down, DNA condenses, spindle begins to form.
Metaphase: replicated chromosomes, which appear as paired sister chromatids, line up across the center of the cell and attach to spindle.
Anaphase: sister chromatids separate and move toward ends of the cell.
Telophase: chromosomes disperse, nuclear envelope reforms.
What completes the M phase of the cell cycle?
Cytokinesis completes the M phase of the cell cycle. It may begin while telophase is still taking place.
During cytokinesis, the cytoplasm (which includes all of the contents of a eukaryotic cell outside the nucleus) draws inward, eventually pinching off into two nearly equal parts. Each part contains a nucleus.
In plant cells and other eukaryotic cells that have a cell wall, a cell plate forms halfway between the divided nuclei. It gradually develops into cell membranes and forms a complete cell wall surrounding each daughter cell.
Upon the completion of cytokinesis and the M phase, a
I'm delighted to share the PDFs of lab courses in Microbial Physiology and Microbial Genetics. These comprehensive resources cover essential topics in understanding the intricate workings of microbes at a physiological and genetic level. these PDFs provide a detailed roadmap for our laboratory explorations.
Microbial physiology is the study of the structure, growth factors, metabolic activities, nutritional requirements, and genetic composition of microorganismsThe microbial cells are extremely complex and in addition to oxygen and hydrogen they contain four other major elements such as carbon, nitrogen, phosphorus and sulphur. here are the notes on microbial physiology..Photosynthetic pigments are the molecules responsible for absorbing electromagnetic radiation, transferring the energy of the absorbed photons to the reaction center, and for photochemical conversion in the photosynthetic systems of organisms capable of photosynthesis.
Probability is the branch of mathematics concerning events and numerical descriptions of how likely they are to occur. The probability of an event is a number between 0 and 1; the larger the probability, the more likely an event is to occur.[note 1][1][2] The higher the probability of an event, the more likely it is that the event will occur. A simple example is the tossing of a fair (unbiased) coin. Since the coin is fair, the two outcomes ('heads' and 'tails') are both equally probable; the probability of 'heads' equals the probability of 'tails'; and since no other outcomes are possible, the probability of either 'heads' or 'tails' is 1/2 (which could also be written as 0.5 or 50%).
These concepts have been given an axiomatic mathematical formalization in probability theory, which is used widely in areas of study such as statistics, mathematics, science, finance, gambling, artificial intelligence, machine learning, computer science, game theory, and philosophy to, for example, draw inferences about the expected frequency of events. Probability theory is also used to describe the underlying mechanics and regularities of complex systems.
Plasmids are extrachromosomal DNA molecules. They are small, circular and have the ability to replicate autonomously. Replication of plasmid is not under the control of chromosomal DNA. They are mostly found in bacteria. Some of the eukaryotes like yeast and plants also contain plasmids.
Download Complete Chapter Notes of Biotechnology: Principles and Processes
Their ability to replicate independently makes plasmid a cloning vector in the recombinant DNA technology for transferring and manipulating genes.
Many antibiotic-resistant genes in bacteria are present in plasmids.
The size of plasmid varies from a few base pairs to thousands of bp.
Plasmids also get transferred from one bacterial cell to another by the process of conjugation.
Plasmids carrying a specific gene are introduced into bacterial cells, which multiply rapidly and the required DNA fragment is produced in larger quantities.
Plasmids are used to prepare recombinant DNA with the desired gene to transfer genes from one organism to another. This is known as genetic engineering.
Joshua Lederberg coined the term plasmid.
mutagen is a physical or chemical agent that permanently changes genetic material, usually DNA, in an organism and thus increases the frequency of mutations above the natural background level. As many mutations can cause cancer in animals, such mutagens can therefore be carcinogens, although not all necessarily are. All mutagens have characteristic mutational signatures with some chemicals becoming mutagenic through cellular processes.
The process of DNA becoming modified is called mutagenesis. Not all mutations are caused by mutagens: so-called "spontaneous mutations" occur due to spontaneous hydrolysis, errors in DNA replication, repair and recombination.
Discovery
The first mutagens to be identified were carcinogens, substances that were shown to be linked to cancer. Tumors were described more than 2,000 years before the discovery of chromosomes and DNA; in 500 B.C., the Greek physician Hippocrates named tumors resembling a crab karkinos (from which the word "cancer" is derived via Latin), meaning crab.[1] In 1567, Swiss physician Paracelsus suggested that an unidentified substance in mined ore (identified as radon gas in modern times) caused a wasting disease in miners,[2] and in England, in 1761, John Hill made the first direct link of cancer to chemical substances by noting that excessive use of snuff may cause nasal cancer.[3] In 1775, Sir Percivall Pott wrote a paper on the high incidence of scrotal cancer in chimney sweeps, and suggested chimney soot as the cause of scrotal cancer.[4] In 1915, Yamagawa and Ichikawa showed that repeated application of coal tar to rabbit's ears produced malignant cancer.[5] Subsequently, in the 1930s the carcinogen component in coal tar was identified as a polyaromatic hydrocarbon (PAH), benzo[a]pyrene.
Polyaromatic hydrocarbons are also present in soot, which was suggested to be a causative agent of cancer over 150 years earlier.
A genetically modified organism (GMO) is any organism whose genetic material has been altered using genetic engineering techniques. The exact definition of a genetically modified organism and what constitutes genetic engineering varies, with the most common being an organism altered in a way that "does not occur naturally by mating and/or natural recombination".[1] A wide variety of organisms have been genetically modified (GM), including animals, plants, and microorganisms.
Genetic modification can include the introduction of new genes or enhancing, altering, or knocking out endogenous genes. In some genetic modifications, genes are transferred within the same species, across species (creating transgenic organisms), and even across kingdoms.
Creating a genetically modified organism is a multi-step process. Genetic engineers must isolate the gene they wish to insert into the host organism and combine it with other genetic elements, including a promoter and terminator region and often a selectable marker. A number of techniques are available for inserting the isolated gene into the host genome. Recent advancements using genome editing techniques, notably CRISPR, have made the production of GMOs much simpler. Herbert Boyer and Stanley Cohen made the first genetically modified organism in 1973, a bacterium resistant to the antibiotic kanamycin. The first genetically modified animal, a mouse, was created in 1974 by Rudolf Jaenisch, and the first plant was produced in 1983. In 1994, the Flavr Savr tomato was released, the first commercialized genetically modified food. The first genetically modified animal to be commercialized was the GloFish (2003) and the first genetically modified animal to be approved for food use was the AquAdvantage salmon in 2015.
Nitrogen-fixing bacteria, microorganisms capable of transforming atmospheric nitrogen into fixed nitrogen (inorganic compounds usable by plants). More than 90 percent of all nitrogen fixation is effected by these organisms, which thus play an important role in the nitrogen cycle.
Two kinds of nitrogen-fixing bacteria are recognized. The first kind, the free-living (nonsymbiotic) bacteria, includes the cyanobacteria (or blue-green algae) Anabaena and Nostoc and genera such as Azotobacter, Beijerinckia, and Clostridium. The second kind comprises the mutualistic (symbiotic) bacteria; examples include Rhizobium, associated with leguminous plants (e.g., various members of the pea family); Frankia, associated with certain dicotyledonous species (actinorhizal plants); and certain Azospirillum species, associated with cereal grasses.
The symbiotic nitrogen-fixing bacteria invade the root hairs of host plants, where they multiply and stimulate formation of root nodules, enlargements of plant cells and bacteria in intimate association. Within the nodules the bacteria convert free nitrogen to ammonia, which the host plant utilizes for its development. To ensure sufficient nodule formation and optimum growth of legumes (e.g., alfalfa, beans, clovers, peas, soybeans), seeds are usually inoculated with commercial cultures of appropriate Rhizobium species, especially in soils poor or lacking in the required bacterium.
Ecosystems can be as large as a desert or as small as a puddle.
They contain biotic
or living parts, as well as abiotic factors
, or nonliving parts. Biotic factors include plants, animals, and other organisms.
Nonliving materials include water, rocks, soil, and sand.
Ecosystems are a chain of interactions between organisms and their environment.
Each organism has a "job" to do in the ecosystem. For example, plants have chloroplasts that enable them to harvest light energy. Then, they take carbon dioxide and water from their environment to convert them into sugar.
Many ecosystems become degraded through human impacts, such as soil loss, air and water pollution, habitat fragmentation
, water diversion, fire suppression, and introduced species
and invasive species
.
An ecosystem includes all the living things (plants, animals and organisms) in a given area, interacting with each other, and with their non-living environments (weather, earth, sun, soil, climate, atmosphere). In an ecosystem, each organism has its own niche or role to play.
L-Lysine is an essential amino acid that's produced by fermentation. The fermentation process uses selected strains of microorganisms that grow in a solution of glucose or molasses, ammonium compounds, inorganic salts, and other substances.
Industrial lysine fermentation is usually performed using large-scale tank fermenters. In production plants, lysine accumulates to a final titer of 170 g/L after 45 hours.
Lysine and other amino acids are commonly produced by fermentation using strains of heterotrophic bacteria, such as Escherichia coli and Corynebacterium glutamicum. C. glutamicum has been engineered to produce lysine with a yield of 0.31 g lysine/g sugar.
Lysine is involved in the production of hormones and energy. It's also important for calcium and immune function.
Amino acids are small molecules that are the building blocks of proteins. Proteins serve as structural support inside the cell and they perform many vital chemical reactions. Each protein is a molecule made up of different combinations of 20 types of smaller, simpler amino acids.The pathways of amino acid synthesis comprise a significant fraction of a bacterium's metabolic activity during its growth in a minimal medium. Two amino acids, glutamine and glutamate, are the immediate products of ammonia assimilation and essential nitrogen donors for the synthesis of other intermediates.
Nutrition is substances used in biosynthesis and energy production and therefore are required for all living things.
Bacteria, like all living cells, require energy and nutrients to build proteins and structural membranes and drive biochemical processes.
Bacteria require sources of carbon, nitrogen, phosphorous, iron and a large number of other molecules.
Carbon, nitrogen, and water are used in the highest quantities.
The nutritional requirements for bacteria can be grouped according to the carbon source and the energy source.
Some types of bacteria must consume pre-formed organic molecules to obtain energy, while other bacteria can generate their own energy from inorganic sources.
Ascomycota is a phylum of the kingdom Fungi that, together with the Basidiomycota, forms the subkingdom Dikarya. Its members are commonly known as the sac fungi or ascomycetes. It is the largest phylum of Fungi, with over 64,000 species.The defining feature of this fungal group is the "ascus" (from Ancient Greek ἀσκός (askós) 'sac, wineskin'), a microscopic sexual structure in which nonmotile spores, called ascospores, are formed. However, some species of the Ascomycota are asexual, meaning that they do not have a sexual cycle and thus do not form asci or ascospores. Familiar examples of sac fungi include morels, truffles, brewers' and bakers' yeast, dead man's fingers, and cup fungi. The fungal symbionts in the majority of lichens (loosely termed "ascolichens") such as Cladonia belong to the Ascomycota.
Ascomycota is a monophyletic group (it contains all descendants of one common ancestor). Previously placed in the Deuteromycota along with asexual species from other fungal taxa, asexual (or anamorphic) ascomycetes are now identified and classified based on morphological or physiological similarities to ascus-bearing taxa, and by phylogenetic analyses of DNA sequences.
A fungus or funguses is any member of the group of eukaryotic organisms that includes microorganisms such as yeasts and molds, as well as the more familiar mushrooms. These organisms are classified as a kingdom, separately from the other eukaryotic kingdoms, which, by one traditional classification, includes Plantae, Animalia, Protozoa, and Chromista.
A characteristic that places fungi in a different kingdom from plants, bacteria, and some protists is chitin in their cell walls. Fungi, like animals, are heterotrophs; they acquire their food by absorbing dissolved molecules, typically by secreting digestive enzymes into their environment. Fungi do not photosynthesize. Growth is their means of mobility, except for spores (a few of which are flagellated), which may travel through the air or water. Fungi are the principal decomposers in ecological systems. These and other differences place fungi in a single group of related organisms, named the Eumycota (true fungi or Eumycetes), that share a common ancestor (i.e. they form a monophyletic group), an interpretation that is also strongly supported by molecular phylogenetics. This fungal group is distinct from the structurally similar myxomycetes (slime molds) and oomycetes (water molds). The discipline of biology devoted to the study of fungi is known as mycology (from the Greek μύκης mykes, mushroom). In the past mycology was regarded as a branch of botany, although it is now known that fungi are genetically more closely related to animals than to plants.
Abundant worldwide, most fungi are inconspicuous because of the small size of their structures, and their cryptic lifestyles in soil or on dead matter. Fungi include symbionts of plants, animals, or other fungi and also parasites. They may become noticeable when fruiting, either as mushrooms or as molds. Fungi perform an essential role in the decomposition of organic matter and have fundamental roles in nutrient cycling and exchange in the environment. They have long been used as a direct source of human food, in the form of mushrooms and truffles; as a leavening agent for bread; and in the fermentation of various food products, such as wine, beer, and soy sauce. Since the 1940s, fungi have been used for the production of antibiotics, and, more recently, various enzymes produced by fungi are used industrially and in detergents. Fungi are also used as biological pesticides to control weeds, plant diseases, and insect pests. Many species produce bioactive compounds called mycotoxins, such as alkaloids and polyketides, that are toxic to animals, including humans. The fruiting structures of a few species contain psychotropic compounds and are consumed recreationally or in traditional spiritual ceremonies. Fungi can break down manufactured materials and buildings, and become significant pathogens of humans and other animals. Losses of crops due to fungal diseases (e.g., rice blast disease) or food spoilage can have a large impact on
Basidiomycetes
Also known as club fungi.
The reproductive structure is basidium.
Spores that are produced are called basidiospores.
The vegetative structure is made up of primary or secondary mycelium.
Vegetative reproduction is done by fragmentation.
Sexual reproduction is done by the two vegetative or somatic cells creating a basidium.
Basidiospores are produced in the basidium by the development of fruiting bodies called basidiocarps.
Examples – Agaricus (found in mushrooms), Puccinia.
Basidiomycetes include these groups: mushrooms, puffballs, jelly fungi, boletes, chanterelles, earth stars, smuts, rusts, mirror yeasts, and Cryptococcus, the human pathogenic yeast.
Lipid metabolism is the synthesis and degradation of lipids in cells, involving the breakdown and storage of fats for energy and the synthesis of structural and functional lipids, such as those involved in the construction of cell membranes. In animals, these fats are obtained from food and are synthesized by the liver. Lipogenesis is the process of synthesizing these fats. The majority of lipids found in the human body from ingesting food are triglycerides and cholesterol.[4] Other types of lipids found in the body are fatty acids and membrane lipids. Lipid metabolism is often considered as the digestion and absorption process of dietary fat; however, there are two sources of fats that organisms can use to obtain energy: from consumed dietary fats and from stored fat.[5] Vertebrates (including humans) use both sources of fat to produce energy for organs such as the heart to function. Since lipids are hydrophobic molecules, they need to be solubilized before their metabolism can begin. Lipid metabolism often begins with hydrolysis, which occurs with the help of various enzymes in the digestive system.Lipid metabolism also occurs in plants, though the processes differ in some ways when compared to animals.[8] The second step after the hydrolysis is the absorption of the fatty acids into the epithelial cells of the intestinal wall.[6] In the epithelial cells, fatty acids are packaged and transported to the rest of the body.[9]
Metabolic processes include lipid digestion, lipid absorption, lipid transportation, lipid storage, lipid catabolism, and lipid biosynthesis. Lipid catabolism is accomplished by a process known as beta oxidation which takes place in the mitochondria and peroxisome cell organelles.
A DNA polymerase is a member of a family of enzymes that catalyze the synthesis of DNA molecules from nucleoside triphosphates, the molecular precursors of DNA. These enzymes are essential for DNA replication and usually work in groups to create two identical DNA duplexes from a single original DNA duplex. During this process, DNA polymerase "reads" the existing DNA strands to create two new strands that match the existing ones.[1][2][3][4][5][6] These enzymes catalyze the chemical reaction
deoxynucleoside triphosphate + DNAn ⇌ pyrophosphate + DNAn+1.
DNA polymerase adds nucleotides to the three prime (3')-end of a DNA strand, one nucleotide at a time. Every time a cell divides, DNA polymerases are required to duplicate the cell's DNA, so that a copy of the original DNA molecule can be passed to each daughter cell. In this way, genetic information is passed down from generation to generation.
Before replication can take place, an enzyme called helicase unwinds the DNA molecule from its tightly woven form, in the process breaking the hydrogen bonds between the nucleotide bases. This opens up or "unzips" the double-stranded DNA to give two single strands of DNA that can be used as templates for replication in the above reaction.
Nuclear magnetic resonance spectroscopy, most commonly known as NMR spectroscopy or magnetic resonance spectroscopy (MRS), is a spectroscopic technique to observe local magnetic fields around atomic nuclei. This spectroscopy is based on the measurement of absorption of electromagnetic radiations in the radio frequency region from roughly 4 to 900 MHz. Absorption of radio waves in the presence of magnetic field is accompanied by a special type of nuclear transition, and for this reason, such type of spectroscopy is known as Nuclear Magnetic Resonance Spectroscopy.[1] The sample is placed in a magnetic field and the NMR signal is produced by excitation of the nuclei sample with radio waves into nuclear magnetic resonance, which is detected with sensitive radio receivers. The intramolecular magnetic field around an atom in a molecule changes the resonance frequency, thus giving access to details of the electronic structure of a molecule and its individual functional groups. As the fields are unique or highly characteristic to individual compounds, in modern organic chemistry practice, NMR spectroscopy is the definitive method to identify monomolecular organic compounds.
The principle of NMR usually involves three sequential steps:
The alignment (polarization) of the magnetic nuclear spins in an applied, constant magnetic field B0.
The perturbation of this alignment of the nuclear spins by a weak oscillating magnetic field, usually referred to as a radio-frequency (RF) pulse.
Detection and analysis of the electromagnetic waves emitted by the nuclei of the sample as a result of this perturbation.
Similarly, biochemists use NMR to identify proteins and other complex molecules. Besides identification, NMR spectroscopy provides detailed information about the structure, dynamics, reaction state, and chemical environment of molecules. The most common types of NMR are proton and carbon-13 NMR spectroscopy, but it is applicable to any kind of sample that contains nuclei possessing spin.
NMR spectra are unique, well-resolved, analytically tractable and often highly predictable for small molecules. Different functional groups are obviously distinguishable, and identical functional groups with differing neighboring substituents still give distinguishable signals. NMR has largely replaced traditional wet chemistry tests such as color reagents or typical chromatography for identification. A disadvantage is that a relatively large amount, 2–50 mg, of a purified substance is required, although it may be recovered through a workup. Preferably, the sample should be dissolved in a solvent, because NMR analysis of solids requires a dedicated magic angle spinning machine and may not give equally well-resolved spectra. The timescale of NMR is relatively long, and thus it is not suitable for observing fast phenomena, producing only an averaged spectrum. Although large amounts of impurities do show on an NMR spectrum, better methods exist for detecting impurities.
Lyophilization or freeze drying is a process in which water is removed from a product after it is frozen and placed under a vacuum, allowing the ice to change directly from solid to vapor without passing through a liquid phase. The process consists of three separate, unique, and interdependent processes; freezing, primary drying (sublimation), and secondary drying (desorption).
The advantages of lyophilization include:
Ease of processing a liquid, which simplifies aseptic handling
Enhanced stability of a dry powder
Removal of water without excessive heating of the product
Enhanced product stability in a dry state
Rapid and easy dissolution of reconstituted product
Disadvantages of lyophilization include:
Increased handling and processing time
Need for sterile diluent upon reconstitution
Cost and complexity of equipment
The lyophilization process generally includes the following steps:
Dissolving the drug and excipients in a suitable solvent, generally water for injection (WFI).
Sterilizing the bulk solution by passing it through a 0.22 micron bacteria-retentive filter.
Filling into individual sterile containers and partially stoppering the containers under aseptic conditions.
Transporting the partially stoppered containers to the lyophilizer and loading into the chamber under aseptic conditions.
Freezing the solution by placing the partially stoppered containers on cooled shelves in a freeze-drying chamber or pre-freezing in another chamber.
Applying a vacuum to the chamber and heating the shelves in order to evaporate the water from the frozen state.
Complete stoppering of the vials usually by hydraulic or screw rod stoppering mechanisms installed in the lyophilizers.
There are many new parenteral products, including anti-infectives, biotechnology derived products, and in-vitro diagnostics which are manufactured as lyophilized products. Additionally, inspections have disclosed potency, sterility and stability problems associated with the manufacture and control of lyophilized products. In order to provide guidance and information to investigators, some industry procedures and deficiencies associated with lyophilized products are identified in this Inspection Guide.
It is recognized that there is complex technology associated with the manufacture and control of a lyophilized pharmaceutical dosage form. Some of the important aspects of these operations include: the formulation of solutions; filling of vials and validation of the filling operation; sterilization and engineering aspects of the lyophilizer; scale-up and validation of the lyophilization cycle; and testing of the end product. This discussion will address some of the problems associated with the manufacture and control of a lyophilized dosage form.
Biological screening of herbal drugs: Introduction and Need for
Phyto-Pharmacological Screening, New Strategies for evaluating
Natural Products, In vitro evaluation techniques for Antioxidants, Antimicrobial and Anticancer drugs. In vivo evaluation techniques
for Anti-inflammatory, Antiulcer, Anticancer, Wound healing, Antidiabetic, Hepatoprotective, Cardio protective, Diuretics and
Antifertility, Toxicity studies as per OECD guidelines
The Roman Empire A Historical Colossus.pdfkaushalkr1407
The Roman Empire, a vast and enduring power, stands as one of history's most remarkable civilizations, leaving an indelible imprint on the world. It emerged from the Roman Republic, transitioning into an imperial powerhouse under the leadership of Augustus Caesar in 27 BCE. This transformation marked the beginning of an era defined by unprecedented territorial expansion, architectural marvels, and profound cultural influence.
The empire's roots lie in the city of Rome, founded, according to legend, by Romulus in 753 BCE. Over centuries, Rome evolved from a small settlement to a formidable republic, characterized by a complex political system with elected officials and checks on power. However, internal strife, class conflicts, and military ambitions paved the way for the end of the Republic. Julius Caesar’s dictatorship and subsequent assassination in 44 BCE created a power vacuum, leading to a civil war. Octavian, later Augustus, emerged victorious, heralding the Roman Empire’s birth.
Under Augustus, the empire experienced the Pax Romana, a 200-year period of relative peace and stability. Augustus reformed the military, established efficient administrative systems, and initiated grand construction projects. The empire's borders expanded, encompassing territories from Britain to Egypt and from Spain to the Euphrates. Roman legions, renowned for their discipline and engineering prowess, secured and maintained these vast territories, building roads, fortifications, and cities that facilitated control and integration.
The Roman Empire’s society was hierarchical, with a rigid class system. At the top were the patricians, wealthy elites who held significant political power. Below them were the plebeians, free citizens with limited political influence, and the vast numbers of slaves who formed the backbone of the economy. The family unit was central, governed by the paterfamilias, the male head who held absolute authority.
Culturally, the Romans were eclectic, absorbing and adapting elements from the civilizations they encountered, particularly the Greeks. Roman art, literature, and philosophy reflected this synthesis, creating a rich cultural tapestry. Latin, the Roman language, became the lingua franca of the Western world, influencing numerous modern languages.
Roman architecture and engineering achievements were monumental. They perfected the arch, vault, and dome, constructing enduring structures like the Colosseum, Pantheon, and aqueducts. These engineering marvels not only showcased Roman ingenuity but also served practical purposes, from public entertainment to water supply.
A Strategic Approach: GenAI in EducationPeter Windle
Artificial Intelligence (AI) technologies such as Generative AI, Image Generators and Large Language Models have had a dramatic impact on teaching, learning and assessment over the past 18 months. The most immediate threat AI posed was to Academic Integrity with Higher Education Institutes (HEIs) focusing their efforts on combating the use of GenAI in assessment. Guidelines were developed for staff and students, policies put in place too. Innovative educators have forged paths in the use of Generative AI for teaching, learning and assessments leading to pockets of transformation springing up across HEIs, often with little or no top-down guidance, support or direction.
This Gasta posits a strategic approach to integrating AI into HEIs to prepare staff, students and the curriculum for an evolving world and workplace. We will highlight the advantages of working with these technologies beyond the realm of teaching, learning and assessment by considering prompt engineering skills, industry impact, curriculum changes, and the need for staff upskilling. In contrast, not engaging strategically with Generative AI poses risks, including falling behind peers, missed opportunities and failing to ensure our graduates remain employable. The rapid evolution of AI technologies necessitates a proactive and strategic approach if we are to remain relevant.
Instructions for Submissions thorugh G- Classroom.pptxJheel Barad
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Welcome to TechSoup New Member Orientation and Q&A (May 2024).pdfTechSoup
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Synthetic Fiber Construction in lab .pptxPavel ( NSTU)
Synthetic fiber production is a fascinating and complex field that blends chemistry, engineering, and environmental science. By understanding these aspects, students can gain a comprehensive view of synthetic fiber production, its impact on society and the environment, and the potential for future innovations. Synthetic fibers play a crucial role in modern society, impacting various aspects of daily life, industry, and the environment. ynthetic fibers are integral to modern life, offering a range of benefits from cost-effectiveness and versatility to innovative applications and performance characteristics. While they pose environmental challenges, ongoing research and development aim to create more sustainable and eco-friendly alternatives. Understanding the importance of synthetic fibers helps in appreciating their role in the economy, industry, and daily life, while also emphasizing the need for sustainable practices and innovation.
Model Attribute Check Company Auto PropertyCeline George
In Odoo, the multi-company feature allows you to manage multiple companies within a single Odoo database instance. Each company can have its own configurations while still sharing common resources such as products, customers, and suppliers.
Macroeconomics- Movie Location
This will be used as part of your Personal Professional Portfolio once graded.
Objective:
Prepare a presentation or a paper using research, basic comparative analysis, data organization and application of economic information. You will make an informed assessment of an economic climate outside of the United States to accomplish an entertainment industry objective.
2. Content :-
■ DNA Replication
■ Facts About Initiation
■ Cell Cycle
■ Initiation Of DNA Replication In Eukaryotes
■ Conclusion
■ Reference
3. DNA Replication :-
■ DNA replication is the process by which a double-stranded DNA molecule is copied
to produce two identical DNA molecules.
■ Replication is an essential process because, whenever a cell divides, the two new
daughter cells must contain the same genetic information, or DNA, as the parent
cell.
■ DNA replication is a semiconservative method.
4. Facts About The Initiation :-
■ We all know that the process of the replication is completed in three steps – Initiation ,
Elongation and Termination.
■ Here, the initiation is the very first and the most important step. Because once the
initiation of the dna replication starts it will end to the termination without any stopage.
■ So, this process of initiation is quite different while we talk about the eukaryotes and the
prokaryotes.
■ In Prokaryotes:- The replication takes place in three steps – Initiation , Elongation and
Termination. So, the whole process of the replication occurs in the S phase of the cell
cycle.
■ In Eukaryotes:- The replication takes place in four steps – Pre-initiation , Initiation ,
Elongation and Termination. Where the pre-initiation step takes place in the G1 phase of
the cell cycle while the rest of the steps gets completed in the S phase of the cell cycle.
5. Cell cycle :-
■ The cell cycle is an ordered series of events involving cell growth and cell division
that produces two new daughter cells. Cells on the path to cell division proceed
through a series of precisely timed and carefully regu lated stages of growth, DNA
replica tion, and division that produce two genetically identical cells.
■ The cell cycle has two major phases: interphase and the mitotic phase. Duringg
interphase, the cell grows and DNA is replicated. During the mitotic phase, the
replicated DNA and cytoplasmic contents are separated and the cell divides
6.
7. ■ Initiation process of the DNA Replication In Eukaryotes is completed in
two steps –
1. Pre-initiation
2. Initiation
Initiation Of DNA Replication In
Eukaryotes:-
8. Pre-initiation :-
■ In this step our pre-replication complex (pre-RC) forms and the process occurs in the G1 phase of
the cell cycle.
■ In the eukaryotesthere are several ORI regions.
■ ORI region is where our replication starts.
■ It is AT rich region. Like in Yeast ARS , it is called AutonomouslyReplicating Site.
■ So, first at the ORI region ORC (Origin of Replication Complex) binds.
■ After this two other proteins called CDC6 and CDT1 binds on the other side of the ORC.
■ After their addition MCM7 protein (which functions as helicase in eukaryotes) binds to the ORC.
■ So, now the complex formed is called as pre-RC (pre-replication complex) and upto this the process
occurs in the G1 phase.
■ In the G1 phase the MCM7 will not show its helicase activity , it will showits activity after its
transition from G1 to S phase.
9.
10. Initiation:-
■ As S phase is the actual replicative phase so now the initiation will start from the S phase.
■ At this stage the MCM-7 becomes active and will show its helicase activity.
■ The transition of MCM-7 from inactive to active is done by kinase enzymes which are CDK and DDK
here.
■ The CDK will phosphorylateCDC6 protein and mark it for degradation.
■ The DDK will phosphorylateMCM-7.
■ The phosphorylation of ORC will also leads to its inactivation.
■ And the CDT1 us inhibited by Germinin protein.
■ The phosphorylation of the MCM-7 leads to the addition of two other proteins named as CDC45
and GINS.
■ Now there will be a formation of CMG Assembly (CDC45-MCM7-GINS).This assembly will now
perform the helicase activity.
11. ■ Now the CMG Assembly will now moves the DNA and melts the ds-DNA to ssDNA by breaking H-
bonds between two strands inorder to provideroom for polymerase enzyme and other enzymes.
■ Formation of CMG Assembly also recruits the MCM-10 and CTF4 proteins to the DNA.
■ Then these two proteins further recruits RPA , Polymerase-alpha proteins and primase
■ Polymerase-alphaand primase are always associated with eachother.
■ RPA protein binds to both the strands and prevents reannealing.
■ Now the primase will add one primer to the leading strand and many to the lagging strand , as
the lagging strand the DNA synthesis is always discontinuous.
■ And after this Polymerase-alpha will show its activity and will add few nucleotides to the primer.
■ The polymerase-delta will then add nucleotides to the strands and the process of elongation
continues.
12.
13.
14. Conclusion:-
■ In Prokaryotes :- The whole replication process ( Initiation , Elongation and
Termination ) takes place in the S phase of the cell cycle.
■ In Eukaryotes:- The Pre-initiation step i.e the formation of pre-replication complex
takes place in the G1 phase of the cell cycle while the rest of the steps ( Initiation ,
Elongation and Termination) takes place in the S phase of the cell cycle.
■ This is the basic relationship present their in betweenthe DNA Replication and the
Cell Cycle.
