Human Genome Complexity, Viruses & Genetic Variability (Learning Objectives) Learn the types of DNA sequences present in the Human Genome other than genes coding for functional proteins. Review what you previously learned about: DNA sequences: non-coding promoters and introns Genes that code for functional RNA such as t-rna and r-rna Pseudogenes, transposons, centromeres, and telomeres Compare and contrast viruses with living cells: structure and functional properties. Learn the biochemical nature of viral components: genome (DNA or RNA), capsid and envelope. Which are present in all or in some viruses? Learn the parasitic nature of viruses and explain: host-cell specificity: relate to common human diseases the steps of the life cycle of animal viruses and association with susceptibility to infection. Role of human genetic variability in susceptibility to viral infections Learn the life cycle of a retrovirus such as HIV and how its genome inserts a copy of itself into the DNA of humans. Explain the role of ancient and current retroviruses shaping the human genome and in adding to the genetic variability crucial for evolution of humans and behavior. Explain the role of ancient and current viral infections as selective pressure affecting human genetic variability
Short Outline Types of DNA sequence in the Human Genome Viruses in general Composition Roles as agents of disease and genetic variability Retroviruses Composition Roles in evolutionary animal diversity and behavior
The Human Genome sequences Most of our genome does not code for proteins - Only 1.5% of human DNA encodes protein - Rest of genome includes: - Promoters and other control sequences - Introns - DNA Sequences for non-coding RNAs - Repeated DNA sequences - DNA of ancient viruses
Noncoding RNAs Nearly all of the human genome can be transcribed as non-coding RNAs (ncrnas), including rrnas and trnas There are hundreds of thousands of other ncrnas - transcribed from pseudogenes - not translated into protein
Repeated DNA Sequences A. Transposons are the most abundant type of repeat - Sequences that jump about the genome B. Other classes of repeats include those that comprise telomeres, centromeres, and rrna gene clusters
Exons (regions of genes coding for protein, rrna, or trna) (1.5%) Repetitive DNA that includes transposable elements and related sequences (44%) Introns and regulatory sequences (24%) Alu elements (10%) Repetitive DNA unrelated to transposable elements (about 15%) Unique noncoding DNA (15%) Simple sequence DNA (3%) Large-segment duplications (5 6%)
Viruses Viruses are genes packaged in protein Biological entities or agents Have no cytoplasm Cannot self-replicate Cannot transform energy Genetic material either DNA or RNA never both
Viruses To replicate they need to infect a living cell Every living cells has one or more viruses that can infect it, specifically.
Basis of Host-Range of Viruses Lock-and-key fit between virus surface and cellular receptors on host cell Narrow host-range with tissue specificity Viruses infect only specific types of cells in one host cold viruses: upper respiratory tract cells. HIV, AIDS virus: a certain white blood cell. Some have a broad host-range infecting multiple species rabies
Viral genomes are made of either DNA or RNA Flu viruses are RNA Genital warts virus (HPV) and Herpes virus are DNA viruses http://www.cdc.gov/std/hpv/stdfact-hpv.htm Membranous envelope RN A Protein coat Glycoprotein spike Influenza HPV
Emerging viruses threaten human health Colorized TEM 50,000 Colorized TEM 370,000 Figure 10.20A, B Ebola Virus (RNA) SARS Virus (RNA)
Naked Viral Shapes Enveloped Complex RNA Capsomere DNA Membranous envelope Capsomere of capsid Glycoprotein Glycoproteins 18 250 nm 70 90 nm (diameter) RNA Capsid Head 80 200 nm (diameter) 80 225 nm DNA Tail sheath Tail fiber 20 nm (a) Tobacco mosaic virus 50 nm 50 nm 50 nm (b) Adenoviruses (c) Influenza viruses (d) Bacteriophage T4
Animal Virus Life Cycle Attachment Entry Uncoating of virion (virus particle) separate protein from NA Replication of nucleic acid (NA) and synthesis of viral proteins Maturation: assembly of NA and proteins Release: cell lysis or budding Role for human genetic variability in completion of viral life cycle
Role of Current Viral infections as selective pressure Influence the genetic variability in human populations Viral genetic variants Host factors: susceptibility genes the host immune response molecular interactions between viral proteins and host proteins throughout viral life cycle
Retroviruses Distinct group of RNA viruses, Retro- reverse transcribe making DNA using RNA template Insert a DNA copy of their genome into the human DNA Can jump from one species to another
Human Immunodeficiency virus (HIV) the cause of Acquired Immunodeficiency Syndrome (AIDS) is a retrovirus http://www.susanahalpine.com/anim/kubyhtml/hiv.htm Envelope Glycoprotein Protein coat RNA (two identical strands) Reverse transcriptase
Viral DNA About 8% of our genome is derived from ancient RNA retroviruses - This is evidence of past infection - Sequences tend to increase over time Figure 11.11
The Virus Hunters (DVD) Retroviruses in human genomes (first 12:30 mins) https://www.youtube.com/watch?v=xtnejngoonk
Primates Monkeys Anthropoids Hominoids (apes) 0 Millions of years ago 10 20 30 40 50 Lorises, pottos, and lemurs Tarsiers New World monkeys Old World monkeys Gibbons Orangutans Gorillas Chimpanzees Humans 60 Ancestral primate
Role for Viruses in shaping the Human Genome Past retroviral infection in a primate ancestor Insertion of sequences New proteins or protein domains for host that maybe beneficial and influence behavior Present retroviral infections influence to the genetic variability of the human populations
The Virus Hunters (DVD) Role of ancient retroviruses in major evolutionary steps (12:30-15:30 mins)
Key evolutionary steps in animal evolution Sponges Cnidarians Flatworms Round worms Molluscs Annelids Arthropods Echinoderms Chordates Segmentation No Body Cavity (No coelom) Mouth from First Embryonic Opening Mouth from Second Embryonic Opening Organ Systems (Coelom) Body Cavity (Pseudocoelom) Tube w/in Tube Radial Symmetry Bilateral Symmetry Sac Body Plan Multicellular Level of Organization
The Virus Hunters (DVD) Role of integrated viruses in explaining complex emotions and behavior (~40:30 to 46:20 mins)