* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Tool box for studying gene function in neural development
DNA vaccination wikipedia , lookup
Nucleic acid analogue wikipedia , lookup
Saethre–Chotzen syndrome wikipedia , lookup
Short interspersed nuclear elements (SINEs) wikipedia , lookup
X-inactivation wikipedia , lookup
Non-coding DNA wikipedia , lookup
Genome (book) wikipedia , lookup
Nucleic acid tertiary structure wikipedia , lookup
Polycomb Group Proteins and Cancer wikipedia , lookup
Genetic engineering wikipedia , lookup
Long non-coding RNA wikipedia , lookup
Genome evolution wikipedia , lookup
Deoxyribozyme wikipedia , lookup
Gene desert wikipedia , lookup
Neuronal ceroid lipofuscinosis wikipedia , lookup
Epigenetics of neurodegenerative diseases wikipedia , lookup
History of genetic engineering wikipedia , lookup
Point mutation wikipedia , lookup
Epigenetics of diabetes Type 2 wikipedia , lookup
Gene therapy wikipedia , lookup
Protein moonlighting wikipedia , lookup
History of RNA biology wikipedia , lookup
RNA interference wikipedia , lookup
Gene therapy of the human retina wikipedia , lookup
Epigenetics of human development wikipedia , lookup
Mir-92 microRNA precursor family wikipedia , lookup
Nutriepigenomics wikipedia , lookup
Gene expression programming wikipedia , lookup
Gene nomenclature wikipedia , lookup
Site-specific recombinase technology wikipedia , lookup
Primary transcript wikipedia , lookup
Gene expression profiling wikipedia , lookup
Epitranscriptome wikipedia , lookup
Helitron (biology) wikipedia , lookup
Vectors in gene therapy wikipedia , lookup
Microevolution wikipedia , lookup
RNA silencing wikipedia , lookup
Non-coding RNA wikipedia , lookup
Designer baby wikipedia , lookup
Therapeutic gene modulation wikipedia , lookup
Molecular tool box for studying gene function in neural development For Eye Development Course Studying gene function in neural development Differential Gene Expression (The Paradigm of Developmental Biology) approx. 30’000 human genes, but … developing roof plate cells express BMP4 signal protein developing floor plate cells express Shh signal protein differentiated neurons express N-tubulin protein oligodendrocytes express myelin-associated glycoprotein lens cells express crystallin protein Differential gene expression from genetically identical nuclear DNA creates different cell types in different parts of the embryo. Studying gene function in neural development Gene Expression DNA GENE transcription (The Central Dogma of Molecular Biology) RNA translation GENE PRODUCTS PROTEIN GENE FUNCTION Studying gene function in neural development Experimental Design I. (“gene A functions in process B”) Investigation of gene expression: gene A is expressed in the appropriate tissue and at the appropriate stage to mediate process B. II. Gain-of-function experiment: gene product of gene A is sufficient for mediating process B. III. Loss-of-function experiment:gene A or gene product of gene A is normally required for process B. IV. Analysing of experiment by investigating the resulting phenotype or marker gene expression. Studying gene function in neural development Methods tool box I. Methods for analysing gene expression (Protein, RNA, Reporter gene (DNA)) (IV. Analyse experiments with tissue-specific molecular markers.) II. Methods for expressing gene products (ectopic expression, over-expression, expression rescue of Protein, RNA or DNA) III. Methods for inhibiting gene function (inhibiting Protein function, disrupting or inhibiting RNA, disrupting gene (DNA)) I. Methods for analysing gene expression Detecting protein expression/localisation • Antibodies: – gel-based methods (“biochemistry”): Western Blot, Proteomics – tissue-based methods (“in situ”): immuno-histochemistry (whole-mount, histology sections) • Protein fusion constructs – artificial chimera protein: fuse endogenous protein coding sequence to • (lacZ (gene) = -gal (protein)) • GFP etc. Western Blot Protein A linked to the enzyme Alkaline Phosphatase (AP) or HRP (chemiluminescent) Protein extraction Protein gel Blot Film Protein A is expressed from stages 10 to 30 during Xenopus development Immunohistochemistry endogenous protein in fixed embryonic tissue Protein A linked to the enzyme Alkaline Phosphatase (AP) or linked to fluorescent molecule coloured precipitate I. Methods for analysing gene expression Detecting RNA expression • Gel-based methods (“Molecular Biology”) – Northern Blot (qualitative, detecting different gene products) – RNase Protection Assay (quantitative), antisense RNA probe forms dsRNA with target mRNA and protects it from RNaseH digest (RNaseH only digests ssRNA). – Microarrays (Analysing the RNA expression of hundreds of genes) – RTPCR (high sensitivity, qualitative, advanced methods are quantitative) • Tissue-based methods (“in situ”) – RNA in situ hybridisation (whole-mount, histology sections) Northern Blot endogenous mRNA of gene A: AAAAAAAAAAAA radioactively labelled DNA probe RNA extraction zygotic RNA maternal RNA RNA gel Blot Film Gene A is expressed maternally and zygotically from stages 10-30 during Xenopus development Maternal and zygotic mRNA from gene A is different size RT-PCR RNA extraction endogenous mRNA of gene A: AAAAAAAAAAAA reverse transcription AAAAAAAAAAAA TTTTTTTTT cDNA of gene A: PCR with radioactive nucleotides TTTTTTTTT radioactive DNA PCR product: DNA gel gene-specific PCR primers Film Gene A is expressed from stages 20 onward during Xenopus development RNA in situ hybridisation I. Methods for analysing gene expression Reporter gene DNA constructs • cis-regulatory DNA elements drive expression of reporter protein. – Lac Z: enhancer prom. ß-galactosidase • very sensitive but only in fixed dead tissue – Green Fluorescent Protein (GFP): enhancer prom. • less sensitive but in live embryos • mutated GFP: CFP (cyan), RFP (red), YFP (yellow) • DsRed is a red fluorescent protein GFP II. Experimental expression of gene products Introducing extra gene product • Fast • Less reliable Introducing an extra gene • Slower, more difficult • more reliable (Transgenics) II. Experimental expression of gene products Introducing extra gene product • Introducing extra protein? doesn’t usually work, not enough protein can be delivered, because there is no amplification step. • Introducing extra RNA: usually works well, because one mRNA molecule produces many proteins. Good for early embryonic stages, since proteins are immediately produced. • Introducing DNA gene constructs: Un-integrated DNA constructs cause mosaic expression, but can be useful if ubiquitous promoters are used to express proteins that function cell-nonautonomously (signals). II. Experimental expression of gene products Delivering extra gene product (into cells) • Microinjection (RNA and DNA): works well with large cells, i.e. early Xenopus and Zebrafish embryos • Electroporation (DNA): works fairly well with Chick neural tissue. • Lipofection: Lipofection reagent facilitates passing of DNA through hydrophobic cell membranes II. Experimental expression of gene products Transgenics (introducing an artificial gene into the genome) • Transgenic mouse (elaborate procedure, mammalian embryo) • Transgenic Xenopus (efficient procedure, vertebrate embryo) • Transgenic Drosophila (P-element transformation) – Plasmid 1: – Plasmid 2: P white+ gene promoter::PROTEIN Transposase gene – TRANSPOSASE integrates plasmid 1 into the Drosophila genome P III. Experimental inhibition of gene function Inhibiting gene products and genes • Inhibiting protein function: good • Disrupting RNA or inhibiting RNA function: better • Disrupting the DNA of the gene: best III. Experimental inhibition of gene function Inhibiting protein function (good) • Pharmacology: small inhibitory molecules, delivery often easy, specificity often difficult to assess. • Dominant-negative protein constructs: mutated proteins that perturb normal function of the endogenous gene product. Fairly advanced knowledge of protein function required. Specificity often difficult to assess, because they inhibit may related gene products from several different genes. • Depletion of endogenous protein using antibodies? works well for extract biochemistry, but mostly unsuccessful or misleading if used in in vivo experimental systems. III. Experimental inhibition of gene function Inhibiting RNA (desrupting RNA) (inhibiting function) “knock down” (better) • double stranded RNA, dsRNA: Disrupts target RNA. – RNAi: (long dsRNA) Works well in Drosophila and C.elegans, but doesn’t work well in neural tissue in C.elegans. – siRNA: (21nt small dsRNA) “silencing” Works in mammalian tissues. • Morpholino antisense oligonucleotides (MO): Inhibits RNA function (interferes with translation initiation or RNA splicing); Xenopus (microinjection), Zebrafish (microinjection), Chicken (delivery difficult). III. Experimental inhibition of gene function Disrupting the gene “knock out” (best) • Targeted knock out (reverse genetics): requires homologous recombination Mouse knock out technology • Integrational mutagenesis: Drosophila P-element mediated integration of exogenous DNA into genome to disrupt endogenous genes. Cloning of affected gene easy because exogenous DNA can be used as a marker. • Classic genetics (forward genetics): start with a mutant phenotype, map mutation (difficult), identify mutated gene Molecular Methods Tool Box Protein RNA DNA (gene) I. Analysis II. Overexpression III. Inhibition •Western Blot •Proteomics •immunohistochemisty •protein chimera •(adding proteins to in vitro reactions) •Northern Blot •RNase protection assays •microarrays •RT-PCR •RNA in-situ •Reporter genes •microinjection •pharmacological inhibitors, •dominant-negative proteins, • protein depletion using antibodies •RNAi & •siRNA •Morpholinos •(microinjection) •Electroporation, •lipofection, •transgenics •Knock-out •Integrational mutagenesis •Classic genetics Question for “Tool box for studying gene function in neural development” lecture in PY4302 course (2004). Question Several powerful molecular tools (or methods) are available to the developmental neurobiologist for studying differential RNA expression in the developing central nervous system of vertebrate embryos. Describe and compare the methods of Northern Analysis (Northern Blot) and RNA in situ hybridisation and their application. Minimal Model Answer: Northern Analysis (alternative correct term Northern Blot) involves the isolation and preparation of RNA from tissue (RNA from tissue taken from different parts of the embryo or from different embryonic stages can be loaded into different lanes and compared with each other), separation of RNA molecules on a gel in an electric field according to differences in mobility (according to size or mass is considered correct), transfer from the gel to a membrane (blotting paper considered correct) and detection of a particular RNA fragment with the help of a labelled (radioactive or epitope-labelled considered correct) antisense probe that hybridises specifically to the particular RNA fragment, followed by detection and imaging (e.g. film) of the resulting bands in columns representing the different lanes of the original gel. RNA in situ hybridisation involves the fixing of embryos or of embryonic tissue under conditions that preserve RNA, incubation with an epitope-labelled (radioactive not taught but also correct if applied to tissue sections) antisense RNA probe that will specifically hybridise to a particular RNA in the tissue, incubation with an enzyme conjugated antibody that recognises and binds the epitope label on the antisense RNA probe, incubation with a colourless substrate that is converted into a coloured precipitate only where the enzyme-conjugated antibody bound to the antisense RNA probe reveals the presence of the particular RNA studied and imaging of the resulting embryo or tissue. More advanced answer: Advantages of Northern Analysis include good resolution for detecting different size gene products (different RNA products from the same gene created by alternative promoters and/or alternative splicing) and of stage-specific differences of expression (depending on the accuracy of the original tissue isolation). Disadvantages include little quantitative information on levels of gene expression and limited resolution for detecting spatial (not cell to cell) differences of expression (depending on accuracy of original tissue isolation). Advantages of RNA in situ hybridisation include good resolution for detecting spatial differences of expression (at least cell to cell, if not on the subcellular level), relatively good information on the temporal differences of expression (depending on the accuracy of the staging). Disadvantages include little quantitative information on different levels of gene expression and usually limited specific information on expression of alternative gene products (depending on the particular probe used).