CHAPTER OUTLINE
... Deoxyribonucleic acid (DNA) is the genetic material of life, it is able to store information that pertains to the development, structure, and metabolic activities of the cell or organism and is stable so that it can be replicated with high accuracy during cell division and be transmitted from genera ...
... Deoxyribonucleic acid (DNA) is the genetic material of life, it is able to store information that pertains to the development, structure, and metabolic activities of the cell or organism and is stable so that it can be replicated with high accuracy during cell division and be transmitted from genera ...
2012 Boc314 TT02m(1) - Learning
... Molecule that when excited by a laser Gives of visible light that can be detected ...
... Molecule that when excited by a laser Gives of visible light that can be detected ...
Gene Expression
... _________________ of RNA to the language of proteins. The instructions for building a protein are written as a series of _______ nucleotide sequences called __________. 2. Translation 2nd step: The protein making machinery, called the ___________, reads the mRNA sequence and translates it into the _ ...
... _________________ of RNA to the language of proteins. The instructions for building a protein are written as a series of _______ nucleotide sequences called __________. 2. Translation 2nd step: The protein making machinery, called the ___________, reads the mRNA sequence and translates it into the _ ...
Teachers Introductory notes for Genetic Modification (GM)
... genes of another. GM can also mean deleting a gene or genes from an organism. Every cell of the new organism then carries those new genes or deletions, and they will pass them on to to any offspring they have. For example, the genes for human insulin have been inserted into a type of bacteria, this ...
... genes of another. GM can also mean deleting a gene or genes from an organism. Every cell of the new organism then carries those new genes or deletions, and they will pass them on to to any offspring they have. For example, the genes for human insulin have been inserted into a type of bacteria, this ...
lecture 2
... • Provides a cell marker that cannot be diluted out. Very valuable for tracing cell lineage. • Can use to study gene function. – Gets around some aspects of pleiotropy. – Allows additional functional tests of genes and pathways. ...
... • Provides a cell marker that cannot be diluted out. Very valuable for tracing cell lineage. • Can use to study gene function. – Gets around some aspects of pleiotropy. – Allows additional functional tests of genes and pathways. ...
Regulation of Transcription
... via universal code – Finally the promoter sequences and gene sequences can be analysed using advanced computational techniques to help understand or suggest how the “operon” works ...
... via universal code – Finally the promoter sequences and gene sequences can be analysed using advanced computational techniques to help understand or suggest how the “operon” works ...
document
... still being studied, but it is thought that these factors are part of a hierarchical, complex, network. • “Transcription factors”: proteins which interact with regions of the DNA to switch genes on. • Interference RNA: a recent discovery. A new type of RNA that, instead of making proteins, stops gen ...
... still being studied, but it is thought that these factors are part of a hierarchical, complex, network. • “Transcription factors”: proteins which interact with regions of the DNA to switch genes on. • Interference RNA: a recent discovery. A new type of RNA that, instead of making proteins, stops gen ...
Slide
... Oligonucleotide sequences (oligos) probes: 25 nucleotide chains for selected parts of a gene complementary to mRNA. For every gene there are 1120(depending on chip design) of different oligo probes called perfect matches (PM). In addition, there are mismatch oligos (MM) corresponding to each of the ...
... Oligonucleotide sequences (oligos) probes: 25 nucleotide chains for selected parts of a gene complementary to mRNA. For every gene there are 1120(depending on chip design) of different oligo probes called perfect matches (PM). In addition, there are mismatch oligos (MM) corresponding to each of the ...
Gene Regulation -
... E. coli grown in lactose as the sole carbon source have about 3,000 copies of the enzyme βgalactosidase/cell. The system of regulation seen here is called "induction" since synthesis of the enzyme is "turned on" only when needed. Induction typically is used to regulate "breakdown" (catabolic) pathw ...
... E. coli grown in lactose as the sole carbon source have about 3,000 copies of the enzyme βgalactosidase/cell. The system of regulation seen here is called "induction" since synthesis of the enzyme is "turned on" only when needed. Induction typically is used to regulate "breakdown" (catabolic) pathw ...
10chap19guidedreadingVideo
... 5. IF cells carry all of the genetic differences, why then are cells so unique – what is responsible for this? 6. In the diagram below – highlight all of the potential locations for gene expression regulation in eukaryotic cells. How does this compare with prokaryotic cells? ...
... 5. IF cells carry all of the genetic differences, why then are cells so unique – what is responsible for this? 6. In the diagram below – highlight all of the potential locations for gene expression regulation in eukaryotic cells. How does this compare with prokaryotic cells? ...
Regulation of gene expression
... • Gene expression vs. Regulation of gene expression • Unicellular organisms: requirements for adaptation to changed environmental conditions. • Multicellular organisms: requirements for the selective expression of genes → relevant differentiation status of various cell types ► cell differentiation ...
... • Gene expression vs. Regulation of gene expression • Unicellular organisms: requirements for adaptation to changed environmental conditions. • Multicellular organisms: requirements for the selective expression of genes → relevant differentiation status of various cell types ► cell differentiation ...
Regulating Protein Synthesis
... ! Eukaryotic cells have many compartments. ! Leader sequences signal import into E.R. ! Transit sequences direct transport into mitochondria, plastids, nuclei. ! Leader, transit sequences generally removed. ...
... ! Eukaryotic cells have many compartments. ! Leader sequences signal import into E.R. ! Transit sequences direct transport into mitochondria, plastids, nuclei. ! Leader, transit sequences generally removed. ...
Analysis of Microarray Data Using R
... Variation in gene expression (as proportion of transcriptome) 95% show at least one 2-fold change among 61 tissues 37% show more than 2-fold differences between lowest 10% and highest 10% ...
... Variation in gene expression (as proportion of transcriptome) 95% show at least one 2-fold change among 61 tissues 37% show more than 2-fold differences between lowest 10% and highest 10% ...
ppt
... TF binding sites) What can these GRNs be used for? functional interpretation of exp. data, guide inhibitor design etc. Limitations of current GRN models: incomplete in terms of TF-interactions, usually do not account for epigenetic effects and miRNAs Bioinformatics 3 – WS 14/15 ...
... TF binding sites) What can these GRNs be used for? functional interpretation of exp. data, guide inhibitor design etc. Limitations of current GRN models: incomplete in terms of TF-interactions, usually do not account for epigenetic effects and miRNAs Bioinformatics 3 – WS 14/15 ...
P systems–based Modelling of Cellular Signalling Pathways
... in biological phenomena is captured by using stochastic strategies . We believe that P systems satisfy the above properties required to a good model. Cellular signalling pathways are fundamental to the control and regulation of cell behaviour. Understanding the biosignalling network functions are cr ...
... in biological phenomena is captured by using stochastic strategies . We believe that P systems satisfy the above properties required to a good model. Cellular signalling pathways are fundamental to the control and regulation of cell behaviour. Understanding the biosignalling network functions are cr ...
Document
... • A bi-product of the glycolytic pathway is lactic acid – this lowers the extracellular pH so that it favours tumour cell proliferation AND it is toxic to normal cells. ...
... • A bi-product of the glycolytic pathway is lactic acid – this lowers the extracellular pH so that it favours tumour cell proliferation AND it is toxic to normal cells. ...
Slide 1
... • Every cell must be able to regulate when particular genes are used cells control gene expression by saying when individual genes are to be transcribed in prokaryotes, genes can be turned off by the binding of a repressor, a protein that binds to the DNA and blocks access to the promoter gene ...
... • Every cell must be able to regulate when particular genes are used cells control gene expression by saying when individual genes are to be transcribed in prokaryotes, genes can be turned off by the binding of a repressor, a protein that binds to the DNA and blocks access to the promoter gene ...
13Johnson
... • Every cell must be able to regulate when particular genes are used cells control gene expression by saying when individual genes are to be transcribed in prokaryotes, genes can be turned off by the binding of a repressor, a protein that binds to the DNA and blocks access to the promoter gene ...
... • Every cell must be able to regulate when particular genes are used cells control gene expression by saying when individual genes are to be transcribed in prokaryotes, genes can be turned off by the binding of a repressor, a protein that binds to the DNA and blocks access to the promoter gene ...
Synthetic biology evolves
... revolutionary field of recombinant DNA technology. There are numerous other examples in which characterized components, which have been tailor-made for specialized function through Nature’s evolutionary process, have been used in novel ways for biotechnological and medical applications. This recipe ...
... revolutionary field of recombinant DNA technology. There are numerous other examples in which characterized components, which have been tailor-made for specialized function through Nature’s evolutionary process, have been used in novel ways for biotechnological and medical applications. This recipe ...
Gene Section POU2AF1 (POU domain, class 2, associating factor 1)
... the transcription of immunoglobulin genes through recruitment to the highly conserved octamer site of immunoglobulin promoters, mediated by either Oct-1 or Oct-2 transcription factor; forms a ternary complex on DNA together with either Oct-1 or Oct-2 transcription factor; is essential for the respon ...
... the transcription of immunoglobulin genes through recruitment to the highly conserved octamer site of immunoglobulin promoters, mediated by either Oct-1 or Oct-2 transcription factor; forms a ternary complex on DNA together with either Oct-1 or Oct-2 transcription factor; is essential for the respon ...
Prokaryotes: genome size: ? gene number: ? Eukaryotes single
... CONTROL OF GENE EXPRESSION means controlling the level of active gene product (this is a broad definition of control of gene expression) this control can be accomplished at different points in the generation of the protein product: transcription: generation of the mRNA copy post-transcription: ...
... CONTROL OF GENE EXPRESSION means controlling the level of active gene product (this is a broad definition of control of gene expression) this control can be accomplished at different points in the generation of the protein product: transcription: generation of the mRNA copy post-transcription: ...
Gene regulatory network
A gene regulatory network or genetic regulatory network (GRN) is a collection of regulators thatinteract with each other and with other substances in the cell to govern the gene expression levels of mRNA and proteins.The regulator can be DNA, RNA, protein and their complex. The interaction can be direct or indirect (through their transcribed RNA or translated protein).In general, each mRNA molecule goes on to make a specific protein (or set of proteins). In some cases this protein will be structural, and will accumulate at the cell membrane or within the cell to give it particular structural properties. In other cases the protein will be an enzyme, i.e., a micro-machine that catalyses a certain reaction, such as the breakdown of a food source or toxin. Some proteins though serve only to activate other genes, and these are the transcription factors that are the main players in regulatory networks or cascades. By binding to the promoter region at the start of other genes they turn them on, initiating the production of another protein, and so on. Some transcription factors are inhibitory.In single-celled organisms, regulatory networks respond to the external environment, optimising the cell at a given time for survival in this environment. Thus a yeast cell, finding itself in a sugar solution, will turn on genes to make enzymes that process the sugar to alcohol. This process, which we associate with wine-making, is how the yeast cell makes its living, gaining energy to multiply, which under normal circumstances would enhance its survival prospects.In multicellular animals the same principle has been put in the service of gene cascades that control body-shape. Each time a cell divides, two cells result which, although they contain the same genome in full, can differ in which genes are turned on and making proteins. Sometimes a 'self-sustaining feedback loop' ensures that a cell maintains its identity and passes it on. Less understood is the mechanism of epigenetics by which chromatin modification may provide cellular memory by blocking or allowing transcription. A major feature of multicellular animals is the use of morphogen gradients, which in effect provide a positioning system that tells a cell where in the body it is, and hence what sort of cell to become. A gene that is turned on in one cell may make a product that leaves the cell and diffuses through adjacent cells, entering them and turning on genes only when it is present above a certain threshold level. These cells are thus induced into a new fate, and may even generate other morphogens that signal back to the original cell. Over longer distances morphogens may use the active process of signal transduction. Such signalling controls embryogenesis, the building of a body plan from scratch through a series of sequential steps. They also control and maintain adult bodies through feedback processes, and the loss of such feedback because of a mutation can be responsible for the cell proliferation that is seen in cancer. In parallel with this process of building structure, the gene cascade turns on genes that make structural proteins that give each cell the physical properties it needs.It has been suggested that, because biological molecular interactions are intrinsically stochastic, gene networks are the result of cellular processes and not their cause (i.e. cellular Darwinism). However, recent experimental evidence has favored the attractor view of cell fates.