Lo studente apprenderà come affrontare uno studio genetico nel campo delle neuroscienze e ne conoscerà alcune delle basi molecolari
Lo studente si confronterà con esempi di patologie del SNC che possono essere ricondotte a difetti genetici, approfondendo possibili strategie di trattamento sia sperimentali che in fasi avanzate di trial clinico.
The student will learn how to deal with a genetic study in neuroscience and will know some of the molecular basis
Le conoscenze saranno verificate tramite esame scritto (orale facoltativo)
Per la parte di Physiological genomics, le conoscenze saranno verificate mediante esame orale
The knowledge will be assessed through written (oral examination optional)
Lo studente acquisirà la capacità di poter progettare (previo approfondimento) studi di tipo genetico per evincere le componenti genetiche di un dato processo (es. neuropatologico)
Verranno forniti esempi di condizioni neuropatologiche a cui applicare le conoscenze di cui sopra
The student will acquire the ability to design (following deepening of the topics) genetic studies to pinpoint the genetic components of a given process (eg. Neuropathological)
Le capacità acquisite sono verificate tramite verifica di esame
The acquired skills are assessed through examination occurs
Lo studente acquisirà occhio critico su come discernere il contributo genetico da quello ambientale in patologie complesse.
Lo studente chiarirà aspetti vantaggiosi e limiti sperimentali e clinici di strategie correttive di malattie genetiche (terapia genica, cellulare etc.)
The student will acquire a critical eye on how to discern the genetic contribution from environment in complex diseases
I comportamenti acquisiti sono verificati tramite verifica di esame
Learned behaviors will be verified at the exam
Sono richieste le conoscenze tipiche del corso di base di Genetica del triennio.
The course requires the typical knowledge of the basic course of the three years Genetics.
E' richiesta una buona preparazione di base nella organizzazione anatomica e funzionale del SNC
Le lezioni sono di tipo frontale
Lessons are Frontal
Introduction to the course. Types of polymorphisms in the genomes. Minisatellites, microsatellites.
DNA fingerprinting, instability of microsatellites. The Slippage-misalignment model.
Neurodisorders for aberrant expansion of triplet microsatellites. Single nucleotide polymorphisms (SNPs), micro-insertions, micro-deletions. Discovery methods: high-resolution melting, single strand conformation polymorphisms, Sanger’s sequencing reaction. Genotyping. DOT BLOT, PCR-RFLP (restriction fragment length polymorphism), ASO-PCR/ARMS (amplification refractory mutation system). Genotyping of SNPs: oligonucleotide ligation assay (OLA), MALDI-TOF, TaqMan Allelic Discrimination Assay. Microarrays for genotyping. The original method: Single base extension (SBE) - Arrayed Primer Extension Assay (APEX). Genotyping with Illumina BeadArray. The Bead decoding. Genotyping by hybridization. Affymetrix GeneChip. PM and MM set probes. Segmental Duplications. Mandatory and optional. Mechanisms of formation: unequal crossing-over, whole-genome duplications, chromosomal rearrangements. The loci of CYP2D6, GSTM1, GSTT1, and TP53 as example of mandatory and polymorphic duplications and interstitial deletions in the human genome. The example of CYP2D6 in the metabolism of antidepressants and other drugs. Genotyping of polymorphic interstitial deletions and small insertions. The example of GSTT1, GSTM1. Analysis of interstitial deletions within the gene of the Duchenne Muscolar Distrophy. Analysis by gel electrophoresis of PCR products, analysis by Multiplex Ligation-dependent Probe Amplification (also called Multiplex Oligonucleotide Ligation Assay), analysis by TaqMan assay (Real-time quantitative PCR). Comparative Genomic Hybridization (Classical CGH). BAC arrayCGH, tiling BAC arrayCGH. SNP array CGH. Interstitial inversions. The example of 900Kbps inversion polymorphisms within 17q21.31 and susceptibility to mental retardation. The forces shaping allele frequencies in populations. How human genome is organized. Satellite DNA, Sat I, II, III, alphoid sequences, beta-sau, organization of centromeric heterochromatin, G and Q bands. Telomeric Minisatellites, multicopy genes (functional RNAs, duplicated genes, pseudogenes, processed pseudogenes). Retrotransposons: LINEs (LINE-1), SINEs (Alu dimer), Endogenous retroviruses, virus-like elements. Mechanisms of retrotransposition. DNA transposons. Mechanism of transposition with and without transposon duplication. Mapping mendelian traits. The first example: Duchenne’s Muscolar Dystrophy. Cloning by subtraction (Kunkel’s method). Examples of genes causative for various types of neurological disorders detected by SNP-arrays in micro-interstitial deletions. Linkage analysis. Principles. Example of LOD score calculation. Two-points mapping, multi-point mapping. The multipoint LOD score. The first high density map of genetic markers (CHLC, CEPH). Mapping homozygosity traits exploiting the autozygosity mapping. Chromosomal segments “Identitcal by Descent” (IBD). The “Identity by State” (IBS). Example of calculation of a LOD score in the offspring of second cousins. Candidate region identified with autozygosity mapping. Narrowing the candidate region exploiting a common ancestor in closed populations. Specific examples (cystic fibrosis, Nijmegen Breakage Syndrome, literature, see slides). Fine mapping in pedegrees (dominant model, an example). Identification of the candidate region by the use of ENU-mutagenized mice. Mice helping to discover the gene for human diseases: the examples of Waardenburg syndrome, and mice shaker-2. The basics of the positional cloning. Pitfalls in linkage studies. After the human genome project: gene predictions, prioritizing genes for mutation scan. The examples of Retinitis pigmentosa, marfan syndrome, Beals’s syndrome, Wilson’s disease, Menkes’s disease. Mutation screening of exons or cDNAs? The example of Haemophilia Factor VIII. Possible landscapes following mutation screening:
1) Good correspondence between genotype and phenotype. Carriers/homozygotes must show the phenotype, healthy people within family should not be carriers or homozygotes.
2) Verify if the variant is a simple polymorphism (Genebank).
3) Go for mutation screeening of the same gene on probands of other families- (a) find the same mutation
(b) find a different mutation (in the same gene)
(c) find no mutations
4) Again: verify these mutations are not polymorphisms (Genebank)
5) Inferring a possible deleterious effect:
(a) evaluating the ORF
(b) use of in silico algorithms predicting the effect on the protein
(c) using the conservation of the region by comparing with evolutionary distant organisms (orthologues) available in Genebank
GENETICS NOW: NEXT GENERATION SEQUENCING MAPPING COMPLEX TRAITS (non mendelian diseases). Introduction to case-control association studies. Hypothesis-driven case-control studies. Selection bias. Stratification bias. The error alpha (type-I error). The error beta (power of the study). Calculation of the Odd Ratio and the 95% confidence intervals. Examples of the genetics models (linear, dominant, recessive). From candidate genes (hypothesis driven studies) to genome-wide associations studies (GWAS, hypothesis generating studies). The Manhattan plots. The problems with multiple testing: the Bonferroni’s correction. A design multistep for a powerful and cost-effective GWAS. SNO-Microarray: the choice of the correct SNPs: the haplotype tagging SNPs. Linkage disequilibrium (LD) and the calculation of the r2. The forces shaping the LD. The hapmap project (www.hapmap.org). Example of extraction of htSNPs. The correct interpretations of the results: association is not causation.
Program of Dr. Enrica Strettoi course
The module will focus on various diseases of the CNS with recognized underlying genetic defects and will illustrate genotype-phenotype correlations and experimental and clinical stage approaches to improve the disease outcome. The visual system will be often used as a paradigm to illustrate concepts and tools that can be extended to the CNS in general. Lectures involving specific CNS areas (commissural system and callosal body; motor areas pertinent to the mirror system; the hippocampus) will be introduced by brief summaries of the main anatomical organization, relevant morphological features, basic nomenclature and interrelations between structures and the rest of the brain.
Specific topics:
Introduction to the course.
Types of polymorphisms in the genomes.
Minisatellites, microsatellites.
DNA fingerprinting, instability of microsatellites.
The Slippage-misalignment model.
Neurodisorders for aberrant expansion of triplet microsatellites.
Single nucleotide polymorphisms (SNPs), micro-insertions, micro-deletions. Discovery methods:
high-resolution melting, single strand conformation polymorphisms, Sanger’s sequencing reaction.
Genotyping. DOT BLOT, PCR-RFLP (restriction fragment length polymorphism), ASO-PCR/ARMS (amplification refractory mutation system).
Genotyping of SNPs: oligonucleotide ligation assay (OLA), MALDI-TOF, TaqMan Allelic Discrimination Assay. Microarrays for genotyping.
The original method: Single base extension (SBE) - Arrayed Primer Extension Assay (APEX).
Genotyping with Illumina BeadArray. The Bead decoding.
Genotyping by hybridization. Affymetrix GeneChip. PM and MM set probes.
Segmental Duplications. Mandatory and optional. Mechanisms of formation: unequal crossing-over, whole-genome duplications, chromosomal rearrangements.
The loci of CYP2D6, GSTM1, GSTT1, and TP53 as example of mandatory and polymorphic duplications and interstitial deletions in the human genome. The example of CYP2D6 in the metabolism of antidepressants and other drugs.
Genotyping of polymorphic interstitial deletions and small insertions. The example of GSTT1, GSTM1. Analysis of interstitial deletions within the gene of the Duchenne Muscolar Distrophy.
Analysis by gel electrophoresis of PCR products, analysis by Multiplex Ligation-dependent Probe Amplification (also called Multiplex Oligonucleotide Ligation Assay), analysis by TaqMan assay (Real-time quantitative PCR).
Comparative Genomic Hybridization (Classical CGH).
BAC arrayCGH, tiling BAC arrayCGH.
SNP array CGH.
Interstitial inversions. The example of 900Kbps inversion polymorphisms within 17q21.31 and susceptibility to mental retardation.
The forces shaping allele frequencies in populations.
How human genome is organized. Satellite DNA, Sat I, II, III, alphoid sequences, beta-sau, organization of centromeric heterochromatin, G and Q bands.
Telomeric Minisatellites, multicopy genes (functional RNAs, duplicated genes, pseudogenes, processed pseudogenes). Retrotransposons: LINEs (LINE-1), SINEs (Alu dimer), Endogenous retroviruses, virus-like elements. Mechanisms of retrotransposition. DNA transposons. Mechanism of transposition with and without transposon duplication.
Mapping mendelian traits. The first example: Duchenne’s Muscolar Dystrophy. Cloning by subtraction (Kunkel’s method).
Examples of genes causative for various types of neurological disorders detected by SNP-arrays in micro-interstitial deletions.
Linkage analysis. Principles.
Example of LOD score calculation.
Two-points mapping, multi-point mapping. The multipoint LOD score. The first high density map of genetic markers (CHLC, CEPH).
Mapping homozygosity traits exploiting the autozygosity mapping. Chromosomal segments “Identitcal by Descent” (IBD). The “Identity by State” (IBS). Example of calculation of a LOD score in the offspring of second cousins.
Candidate region identified with autozygosity mapping. Narrowing the candidate region exploiting a common ancestor in closed populations. Specific examples (cystic fibrosis, Nijmegen Breakage Syndrome, literature, see slides).
Fine mapping in pedegrees (dominant model, an example).
Identification of the candidate region by the use of ENU-mutagenized mice. Mice helping to discover the gene for human diseases: the examples of Waardenburg syndrome, and mice shaker-2.
The basics of the positional cloning. Pitfalls in linkage studies.
After the human genome project: gene predictions, prioritizing genes for mutation scan. The examples of Retinitis pigmentosa, marfan syndrome, Beals’s syndrome, Wilson’s disease, Menkes’s disease. Mutation screening of exons or cDNAs? The example of Haemophilia Factor VIII.
Possible landscapes following mutation screening:
1) Good correspondence between genotype and phenotype. Carriers/homozygotes must show the phenotype, healthy people within family should not be carriers or homozygotes.
2) Verify if the variant is a simple polymorphism (Genebank).
3) Go for mutation screeening of the same gene on probands of other families- (a) find the same mutation
(b) find a different mutation (in the same gene)
(c) find no mutations
4) Again: verify these mutations are not polymorphisms (Genebank)
5) Inferring a possible deleterious effect:
(a) evaluating the ORF
(b) use of in silico algorithms predicting the effect on the protein
(c) using the conservation of the region by comparing with evolutionary distant organisms (orthologues) available in Genebank
Complex traits (non mendelian diseases).
Introduction to case-control association studies.
Hypothesis-driven case-control studies. Selection bias. Stratification bias.
The error alpha (type-I error). The error beta (power of the study).
Calculation of the Odd Ratio and the 95% confidence intervals. Examples of the genetics models (linear, dominant, recessive).
From candidate genes (hypothesis driven studies) to genome-wide associations studies (GWAS, hypothesis generating studies).
The Manhattan plots. The problems with multiple testing: the Bonferroni’s correction. A design multistep for a powerful and cost-effective GWAS.
SNO-Microarray: the choice of the correct SNPs: the haplotype tagging SNPs. Linkage disequilibrium (LD) and the calculation of the r2. The forces shaping the LD. The hapmap project (www.hapmap.org). Example of extraction of htSNPs.
The correct interpretations of the results: association is not causation.
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The course will focus on various diseases of the CNS with underlying genetic defects to illustrate genotype-phenotype correlations and experimental and clinical stage approaches to improve the disease outcome. The visual system will be often used as a paradigm to illustrate concepts and tools to which other genetic diseases of the CNS will be compared to obtain general concepts. Lectures involving specific CNS areas (i.e. the callosal body; motor areas pertinent to the mirror system; the hippocampus etc.) will be introduced by summaries of the main anatomical organization, relevant morphological features, basic nomenclature and position in the brain general context as well as fundamental of physiology. Indications for usage of web-based tools to navigate the brain will be provided. Various topics will comprise an experimental part illustrating modern methodological tools for the study of the CNS. Navigation and search of clinicaltrials.gov for the genetic diseases under study will be performed.
Specifically:
1) Text book (suggested):
"Genetica molecolare umana ", by Tom Strachan & Andrew P. Read (Zanichelli)
"Introduzione alla Genomica", by Greg Gibson & Spencer Muse (Zanichelli)
"Principles of Neural Science", by Eric R. Kandel, J.H. Schwartz and other Authors (5th edition suggested, but previous editions are also valid)
2) Original articles, recommended websites for specific studies, video material will be provided to the students through direct access to a common site created ad hoc.
Articoli originali, indicazioni di siti web raccomandati per lo studio di argomenti specifici, materiale video etc. saranno forniti agli studenti mediante accesso a un link comune creato per la condivisione di materiale didattico.
Text book (suggested):
"Genetica molecolare umana ", by Tom Strachan & Andrew P. Read (Zanichelli)
"Introduzione alla Genomica", by Greg Gibson & Spencer Muse (Zanichelli)
Tutte le info si trovano nei siti web del corso
See
www.stefanolandi.eu
L'esame è scritto e prevede una parte di esercizi, una parte come domanda aperta, e una relazione su un articolo scientifico scelto anticipatamente. Una prova orale è facoltativa con possibilità di modificare la votazione dlela prova scritta di -/+ 1 punto
Per la parte di Physiological Genomics (Dott. E. Strettoi) l'esame è orale
The exam is written (2 hours). An oral can be requested (optional) but it will change the final score of only + or - 1 point
Cercare su e-learning o Moodle
Per il materiale di Physiological Genomics è stato creato un gruppo aperto a tutti gli iscritti dove è raccolto tutto il materiale didattico
Look at
e-learning
Moodle