Chapter 11 - useful links

... By now you may have figured out that genes(alleles) segregate or separate from each other because they are attached to chromosomes which separate during meiosis. Also, genes do not assort themselves independently. It is the chromosomes that assort themselves independently because of the way they lin ...

Sample Size Calculations for Matched

... This routine computes the sample size n required to achieve a specified power level 1 − β1 for a matched-pairs design in which differential expression between n treatment units and n matched control units is of interest. The total number of experimental units for the study is 2n. The following list ...

DNA/RNA.lecture

... C. Overview: information flow & gene expression II. Transcription A. Structure 1. nucleotide differences 2. RNA 3. short B. When does this happen? C. 3 main kinds of RNA 1. messenger RNAs (mRNA) 2. Other 2 types of RNA - protein-producing machinery a. transfer RNAs (tRNA) b. ribosomal RNAs (rRNA) D. ...

Biotechnology

... • Uses computer databases to organize and analyze biological data, such as genes and proteins. ...

Project : Operon Prediction - Bioinformatics at School of Informatics

... very strong intuition to understand the genome structure. Conserved gene neighborhoods reconstructed from many genomes by the Tiling Path Method can be used to predict the functions of uncharacterized genes and functional coupling between well-characterized genes in those genomes. Ultimately, We can ...

Structure of biological networks

... connect couples of nodes, even if the network has a very large number of nodes. This phenomenon is observed also in certain classes of irregular but non-random networks – in fact the phenomenon was first observed in social networks back in the sixties of the 20th century. Social studies show that in ...

16.1 * Producing DNA Fragments

... then transferring it into microorganisms. • The microorganisms then act as ‘factories’ where the gene product (the desired protein) is continuously manufactured. An example: The production of Insulin ...

Biology Notes: Cell Membrane

... - Protein channels: allow objects to __________________ - Enzymes: _________________ ________ chemical reactions - Markers (carbohydrate chains): cell ____________________; ________________ _________________ ...

Genomics: Understanding the Blueprint of Life

... Custom software: getting representative value of a probe cell ...

Power point

... • During embryonic development, a fertilized egg gives rise to many different cell types • Cell types are organized successively into tissues, organs, organ systems, and the whole organism • Gene expression orchestrates the developmental programs of animals ...

chapt13_image

... • A gene mutation is a permanent change in the sequence of bases in DNA • Can range from no effect to complete inactivation • Germ-line mutations occur in sex cells and can be passed to subsequent generations • Somatic mutations occur in body cells and affect only a small number of cells in a tissu ...

401Lecture5sp2013post

... Each probe specific for sequences separated by known distances in linear Fig. 6-35 Lodish et al. 2013 DNA What result would you expect if DNA exists in loops? Would you expect loops to be present at all stages of cell cycle? ...

GPSDB: a new database for synonyms expan

... name, entry ID, etc.). In order to retrieve a complete list of synonyms for a given gene/protein, all entries from the databases above relating to a same entity were merged. The identification and connection of such entries was achieved by making use of the (transitive and symmetric) database cross- ...

Cell and Cell Metabolism Quiz

... It allows everything to enter but is selective about what leaves. The membrane is permeable only during optimal cell conditions. It allows some substances to pass through and keeps others out. It is selective about what enters but will allow everything to leave the cell. ...

Most fundamental cellular processes are not

... for transferring regulatory relationships between organisms. We pioneered using 3D molecular structures for analysis of protein networks (Kim et al. 2006; Kim et al. 2008). This work showed that much of the debate on the degree of conservation of hubs could be resolved by focusing on the number of s ...

Chapter 6

... The sequences of homologous genes in different species vary at replacement sites (where mutation causes amino acid substitutions) and silent sites (where mutation does not affect the protein sequence). Mutations accumulate at silent sites 10faster than at replacement sites. The evolutionary diver ...

Chapter 1: Overview of Genetics

... 2. Charles Darwin proposed the theory of natural selection as the mechanism for biological evolution. 3. Over a long period of time, the accumulation of many genetic changes may lead to rather striking modifications in a species’ characteristics (Figure 1.11). 1.3Fields of Genetics Learning Outcomes ...

DNA Transcription and Translation

... In the process of transcription, a gene is copied and the information is taken out of the nucleus so that the cell can make a protein out of the information obtained from the DNA in the gene Every 3 nitrogen bases in the DNA that makes up a gene is called a codon, and codes for a specific amino ...

A primer on the structure and function of genes

... structural diversity arose via local changes in the DNA sequence of genes. The deterministic view of the gene was not only popular, but productive; without it we could not have identified the genetic basis of many diseases. In fact, one of the motivating factors behind the huge effort and expense of ...

Lecture1cont

... Phylogeny Evolution - a process in which small changes occur within species over time. These changes could be monitored today using molecular techniques. ...

biology – semester 2 study guide

... Galapagos islands. His book Origin of Species – emphasized competition for resources, and variability within populations. Evidence of evolution includes homologous structures and analogous structures. Patterns of evolution - Convergent evolution, divergent evolution, co-evolution.. Similarity in DNA ...

Last5

... • Sanger-Schachter theory of emotion: emotion is a function both of cognition (thought) and physiological state • these lead to the bonds we form: we know that oxytocin (involved in maternal bonding/imprinting with offspring) and vasopressin are two key players ...

**** 1 - School of Life Sciences

... healthcare system. In the first part of lecture, I will discuss nanosatellites that have multiple functions in living systems: targeting, imaging, gene delivery and regulations. Magnetic nanosatellites are being developed as new classes of smart MRI contrast agents, molecular diagnostic probes, magn ...

Slide 1

... Akinetes differentiate upon P limitation but not under N, DIN, Fe, trace elements or light limitation. ...

Bioinformatics and Functional Genomics, Chapter 8, Part 1

... Inferred by curator Inferred from direct assay Inferred from electronic annotation Inferred from expression pattern Inferred from genetic interaction Inferred from mutant phenotype Inferred from physical interaction Inferred from sequence or structural similarity Non-traceable author statement No bi ...

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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.

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Gene regulatory network