1. BIO 224 Intro to Molecular and Cell Biology
DNA and Chromosomes
BIO 224
Intro to Molecular and Cell Biology

2. Heredity All organisms get genetic information from parents
All cells come from pre-existing cells
All genetic material needs to be replicated and passed on from parent to progeny at each cell division
Molecular biology seeks to understand heredity at the molecular level

3. Genes and Chromosomes
Mendel described classical genetics principles with pea plant experiments
Characteristics carried on inherited factors called genes
Sexually reproducing organisms get one copy from each parent, called alleles
Dominant alleles mask the recessive allele
Genotype is the genetic makeup, phenotype is the physical expression

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6. Chromosomes
Late 1900s role of chromosomes as carriers of genes proposed
Most higher plant and animal somatic cells diploid
Gametes (germ cells) haploid
Union of haploid gametes produces diploid zygote
Relationships of mutation, genetic linkage, and chromosomes worked out in Drosophila in 1900s by T.H. Morgan
Breeding experiments with various mutant strains revealed traits that were linked and those on different chromosomes
1909 first understood how genes led to phenotypes
Beadle and Tatum’s experiments with enzyme deficient mutants led to one gene, one enzyme hypothesis now one gene, one polypeptide
1915 chromosome basis of heredity widely accepted
Originally thought proteins were carriers of genetic material because of presence in chromosomes
DNA was not “complex” enough to carry genetic information

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8. Chromosomes Prokaryote and eukaryote chromosomes differ
Prokaryote DNA in single circular chromosome
Eukaryote genomes made of multiple chromosomes with linear DNA molecules
All eukaryotes have same basic chromosome structure but can vary in size and number
DNA bound to small basic histone proteins that help package DNA into cells’ nuclei
DNA and associated proteins make up chromatin

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10. Chromatin Contains 2X protein to DNA Histones are major proteins
5 types, similar in different eukaryotes
Over 1000 kinds of nonhistone proteins, involved in DNA replication and gene expression
Nucleosome is basic structural unit
DNA wrapped around histone core
Contributes to DNA coiling and chromatin condensation
Chromatosome is subunit with nucleosome core locked in place by histone protein
Highly condensed chromatin in interphase is heterochromatin, not transcriptionally active, making up centromere and telomeres
Euchromatin is decondensed in interphase for replication and transcription prior to cell division

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13. 5.13 Chromatin fibers
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15. Chromosomes
Condense when entering mitosis for distribution of material to daughter cells
Transcription ends when condensation occurs
Centromeres ensure correct distribution of duplicated chromosomes to daughter cells during mitosis
Hold sister chromatids together during mitosis and allow for spindle tubule attachment
Specific DNA sequences found there for binding of associated proteins forming kinetochore
Telomeres are sequences at ends of eukaryotic chromosomes
Sequences have clusters of Gs, allows loop formation
Important in chromosome replication and maintenance
Seem to have role in lifespan and reproductive capability of cells
Damage or loss of portions of telomeres associated with human disease

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23. DNA as Genetic Material
Experiments in 1928 with Pneumococcus bacteria showed a “transforming principle” was responsible for conversion of R strains to S strains
1944 experiments by Avery, MacLeod, and McCarty showed transforming principle to be DNA
Established DNA as the genetic material

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25. DNA Structure 1953 Watson and Crick discovered 3-D structure of DNA
Known to be 4 base polymer of 2 purines (A & G), 2 pyrimidines (C & T) plus attached phosphorylated sugars
X-ray crystallography studies, H-bonding evidence, base pair ratios led to DNA model
Double helix with phosphate-sugar backbone, turns every 3.4 nm
Bases internally H-bonded in complementary fashion
Purines pair with pyrimidines (A-T and G-C)
One strand carries the information to dictate sequence of the other strand

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28. DNA
Provides blueprint to direct cellular activities and specify development in multicellular organisms
Recombinant DNA techniques have allowed sequencing of whole genomes
Complete sequences available for several organisms

29. Eukaryote Genomes Larger and more complex than prokaryotes
Complexity not necessarily related to size
Most eukaryotic cells have functional and nonfunctional DNA sequences
Most higher eukaryotes have large amount of noncoding sequences

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31. Genome Organization
A gene is a sequence of DNA expressed to yield a final product like RNA or protein
Some noncoding sequences in eukaryotes are spacers between genes
Eukaryote DNA contains introns and exons
Exons are coding regions of genes
Introns are sequences between exons
Entire gene is transcribed to mRNA and introns are spliced out
Introns have no known function
May contain more DNA than exons
Allow for different combinations of exons, giving multiple products from one gene by alternative splicing
Allow exon shuffling- recombination of exons from different genes
Lead to new genes or chimeras

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34. Repetitive Sequences
Large portions of complex eukaryote genomes have repeated noncoding DNA sequences
Can be hundreds to thousands, even millions, of copies
Up to 50% of mammalian DNA made of highly repetitive sequences
Several types of repeats were identified by sequence analysis

35. Repetitive Sequences
Repetitive sequences and introns contribute to most of the genome size of higher eukaryotes
Simple sequence repeats (SSR) are tandem arrays of short sequences, up to thousands of copies
Will form separate bands from main DNA called satellite DNAs
Not transcribed, have no functional information, make up part of chromosome structure
SINEs and LINEs found throughout genome, not in tandem
Both are examples of transposable elements
SINEs are bp, 1.5 million copies, transcribed but not translated, function unknown
LINEs are 4-6 kb, 8.5X105 copies, some transcribed and translated, function unknown

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37. Transposable Elements
Capable of moving to different sites in genomic DNA
Retrotransposon transposition mediated by reverse transcriptase
SINEs and LINES are retrotransposons
Retrovirus-like elements resemble retroviruses and also move by reverse transcriptase activity with 45,000 in human genome, from 2-10 kb
DNA transposons are copied and re-inserted as DNA sequences with up to 300,000 copies in genome, from 80 to 3000 bp

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40. Gene Duplication and Pseudogenes
Genes present in multiple copies, many nonfunctional
Need multiple genes for RNA or proteins needed in large quantities
Gene families are members of related groups of genes transcribed in different tissues or different developmental stages
Thought to have originated due to one of two mechanisms
Duplication of block DNA sequence that moved to new location
Range from 1kb to 50 kb
Copies of genes mutated until they are nonfunctional become pseudogenes
Duplicate obtained by reverse transcription, copies lack introns and sequences to direct transcription, are nonfunctional
Becomes a processed pseudogene

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44. Disclaimer
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