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)

For the section Clinical Genetics (Prof. I. Maystadt):

This introductory course in clinical genetics provides the fundamentals of the profession of clinical geneticist and the essential steps in a genetics consultation, distinguishing between diagnostic and predictive testing. It offers a structured exploration of clinical cytogenetics, presenting the main chromosomal analysis techniques and major associated syndromes, as well as the mechanisms underlying the occurrence and transmission of chromosomal and monogenic disorders. Students are also introduced to genetic counseling principles, variant classification, and diagnostic strategies tailored to each pathological context, while addressing both the human and practical considerations involved in the communication of genetic diagnoses.