Genetics

1.Introduction

• The germline is continuous
• Genetics, human genetics, medical genetics, somatic “genetics”
• Impact of genetic diseases on human health
• Relationships between genes, environment, and phenotypes
• Historical background of some fundamentals of genetics
• Mendel’s discoveries: the concept of the gene
• Mendel's laws
• Chromosome theory of inheritance
• Genes are linked to chromosomes
• Meiosis
• Genetic linkage and crossing-over
• Chromosome mapping
• The origin of genetic variability, mutations
• Nucleic acids transmit genetic information
• Avery’s unexpected discovery: DNA can carry genetic specificity
• The double helix
• Genetic information contained in DNA is encoded in the sequence of the four nucleotides
• The central dogma
• Crick’s adaptor hypothesis
• Discovery of tRNAs
• Discovery of mRNAs
• Establishment of the genetic code
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2. Structure of Nucleic Acids

• The DNA double helix
• DNA topology
• Structure and functions of RNA (including slides on RNA viruses and their cycle)

3. Organization of Genomes

• Size, organization
• Repeated sequences
• Mammalian transposable elements (LINE, SINE, LTR, ERV)
• LINE transposition

4. Structure of Chromosomes

• Centromeres
• Origins of replication
• Telomeres
• Replication of the ends of linear chromosomes
• Telomerase
• Chromatin structure
• The nucleosome
• Higher-order chromatin structures
• Regulation of chromatin structure
• Histone modifications

5. DNA Replication

• Initiation, activation of replication origins
• Helicases, topoisomerases, primase, DNA polymerases

6. Mutations

• Different types of mutations
• Origin of mutations

7. DNA Damage and Repair

• Nature of DNA damage
• Chemical modifications of the bases (altered bases, missing bases)
• Deaminations
• Base oxidation
• Hydrolysis (base loss)
• Alkylations
• Pyrimidine dimers
• Base mismatches
• Intrabranch and interbranch crosslinks
• DNA-protein crosslinking
• Single-strand and double-strand breaks of the ribose-phosphate backbone
• Causes of DNA damage
• Spontaneous damage
• Induced damage by mutagenic "agents" (chemicals, UV and ionizing radiation)
• Ionizing radiation
• Chemical mutagens
• The Ames test detects the mutagenic potential of a substance
• Repair mechanisms and “trans-lesion” DNA synthesis (TLS)
• Repair of a damaged base
• Direct reversal of DNA damage
• Base excision repair (BER)
• Repair of bulky lesions
• Nucleotide excision repair (NER)
• Repair of mismatches (mismatch repair, MMR)
• Interstrand cross-link repair (ICL)
• Repair of double-strand breaks:
• Non-homologous end joining (NHEJ)
• Homologous recombination, gene conversion
• Clinical consequences of DNA repair defects

8. Cytogenetics and Concepts of Epigenetics

• Observation and description of chromosomes (banding)
• Chromosomal abnormalities
• Definition
• Different categories of abnormalities
• Numerical and structural abnormalities
• Cytogenetic nomenclature
• Balanced and unbalanced abnormalities
• De novo and inherited abnormalities
• Causes of aneuploidies
• Clinical consequences of abnormalities
• Autosomal aneuploidies
• Causes of Down syndrome
• Sex determination
• Sex chromosome abnormalities
• X chromosome inactivation
• DNA methylation and concepts of epigenetics
• Sex chromosome abnormalities
• Parental origin chromosomal abnormalities
• Parental imprinting
• Diploidy and uniparental disomies
• Causes of Prader-Willi and Angelman syndromes

9. Genome Expression: Transcription

• Initiation complex, transcription factors
• Elongation
• Termination and polyadenylation
• Intron splicing

10. Genes in Pedigrees and Populations

• Patterns of Mendelian pedigrees
• Complications compared to Mendelian pedigrees
• Genetics of multifactorial traits: the polygenic threshold theory
• Factors affecting allele frequencies
• Use of Hardy-Weinberg equilibrium in genetic counseling
• New mutations, selection, genetic drift

11. Mapping and Identification of Genes Controlling Monogenic Traits

• Positional cloning
• Functional cloning
• Genome-wide association studies
• Genome and exome sequencing
• Confirmation of the candidate gene

12. Human Genetic Variability and Its Consequences

• Types of variation between individual genomes (SNPs, repeat number, large-scale variants)
• Pathogenic DNA variants (missense, nonsense, frameshift mutations, dynamic mutations)
• Molecular pathology: understanding the impact of pathogenic variants
• Loss of function vs. gain of function
• Allelic heterogeneity in loss of function
• Haploinsufficiency
• Dominant negative effect
• Gain-of-function mutations often affect regulatory pathways
• Allelic homogeneity is not always linked to gain of function

13. Essentials of Molecular Biology (Methods):

• Cloning of DNA fragments in cells
• Electrophoresis
• Nucleic acid hybridization
• FISH
• Sanger DNA sequencing
• Southern blot, Northern blot
• PCR
• Transcriptomics by RNA microarray and RNAseq
• CGH array
• CRISPR/Cas9 and genome editing (very brief)