MBG Final

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(Fall 2013) Flashcards on MBG Final, created by j_sunga on 21/10/2013.
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Flashcards by j_sunga, updated more than 1 year ago
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Resource summary

Question Answer
Functions of genetic material (3) replication, expression, mutation
Explain Levene's Tetranucleotide hypothesis A=T=C=G, too simple to store information therefore structural role
discovery by Avery, MacLeod, McCarty DNA = transforming principle, removing anything else had no effect on transformation
Hershey Chase Experiment tagging protein and DNA in bacteriophages, DNA is transferred to cell
differences between RNA and DNA U instead of T, single stranded, ribose vs. deoxyribose
basic DNA structure nitrogenous base + sugar + phosphate
Chargaff's Rules G=C and A=T, composition varies between species
discovery of DNA structure Franklin and Wilkins, Watson and Crick
Chromosome structure in prokaryotes 1 DNA molecule, circular chromsome, form nucleoid, supercoiled. Supercoiled and folded (loops) in bacteria
Levels of chromosome condensation in Eukaryotes 1. nucleosome 2. chromatin fibre 3. metaphase chromosome
histones of octomer H2a, H2b, H3, H4
alpha satellite sequence 171bp sequence repeated in human centromere
centromere complex numerous proteins that contact 20-30 microtubules
possible models of DNA replication conservative, semiconservative, dispersive
evidence from autoradiography After meiosis 1 – both chromatids labeled, after 2 – only one labeled
replicon region controlled by an origin (entire chromosome)
origin site of initiation of DNA synthesis (1/chromosome)
Okazaki fragments small strands synthesized in lagging strand
Roles of DNA polymerase 1 (3) 5'-3' polymerization, both 3'-5' and 5'-3' exonuclease activity
Exonuclease starts at either end of the DNA molecule
endonuclease cleaves at internal sites
Activities of DNA polymerases (3) polymerization, proofreading, primer removal
functions of DNA polymerase I on lagging strand removes RNA primers, fills in gaps (ends joined by DNA ligase)
Proteins involved in initiation of DNA replication (3) preprimers, DnaA, DnaB (helicase) and DnaC
DNA topoisomerase I produces temporary single strand breaks
DNA topoisomerase II produces temporary double strand breaks
DNA gyrase cleaves both strands, passes one over the other, then reseals
Components of E. coli DNA polymerase III Holoenzyme, Catalytic core (alpha, ɛ, θ), sliding clamp (2 β subunits)
Primosome = DNA primase + DNA helicase, includes all steps from unwinding to ligase
replisome = primosome + pol III holoenzyme
main differences between replication in prokaryotes and eukaryotes (4) S phase, pairs of linear chromosomes, multiple origins, packaged in nucleosomes
polymerases in eukaryotic DNA replication (4) Pol ɛ replicates leading strand, Pol ɗ extends RNA/DNA primer on lagging strand, Pol α + DNA primase prime and synthesize Okazaki fragments
function of ribonuclease H1 and FEN-1 remove RNA primers
telomere functions (3) prevent fusion with other ends, prevent degradation by endonucleases, facilitate end replication
shelterin coats t-loop to protect from degradation
Reverse transcriptase synthesizes DNA using RNA template
1 gene/ 1 ribosome hypothesis each ribosome contains RNA that directs synthesis of a unique protein (wrong)
Properties of mRNA polymer of ribonucleotides, linked by phosphodiester bonds, U instead of T, unstable, transient
types of RNA mRNA, tRNA, rRNA, hnRNA, snRNA, miRNA
RNA polymerase structure in E.Coli Holoenzyme: α2ββ’σ, Core enzyme: α2ββ’
Consensus sequences within -35 and -10,comparison for promoter sequences to determine strength
3 steps of Initation RNAP holoenzyme binds promoter region, DNA unwinding, bond formation
3 steps of termination chain termination (RNAP encounters signal), RNA pol/DNA complex dissociates, RNA transcript released
Rho-independent vs dependant terminators independant - G:C rich repeats, forms hairpin, ends with ~6A's. dependent - rho utilization (rut)
functions of RNAP's in eukaryotes I - rRNA, II-mRNAs, III - tRNA, 5s rRNA, some snRNA
Nucleolus site of rRNA synthesis by RNAP I and ribosome assembly
monogenic each mRNA encodes only a single polypeptide
Three general control elements TATA box, promoter proximal elements, enhancer elements
chromatin remodelling factors methylation - nucleosome compaction, acetylation - nucleosome free regions
eukaryotic promoters complex, contain multiple enhancer and repressor elements, small change = major phenotypic effects
modifications to eukaryotic mRNA capping 5' end, tailing 3' end, splicing (intron removal), editing
functions of 5' cap prevent degradation, recognition by ribosome
mRNA editing methods insertion/deletion of nucleotides, conversion of one base to another (C-U editing) - rare in animals
Exons and introns Exons: expressed sequence, Introns: intervening sequence
genes without introns interferon, heat shock proteins, histones
functions of introns contribute to evolution of protein families, multiple introns increase protein-coding potential
alternative splicing same gene can produce different proteins
Splicing Mechanisms (3) endonucleolytic cleavage and ligation, autocatalytic splicing, spliceosome-mediated
spliceosome components 5 types of snRNA: U1,2,4,5,6 and ~40 different proteins forming snRNPs
amino acid structure amino, carboxyl and R group, joined together by peptide bonds
translation machinery (5) ribosomes, tRNA, amino acid-activiating enzymes, initiation/elongation/termination factors, mRNAs
steps in translation initiation prepare 30 S subunit and initiator tRNA, formation of 30S initiation complex, formation of 70S ribosome particle
steps in translation elongation specific aminoacyl-tRNA binds to A site, formation of peptide bond (join aa), ribosome moves to next codon towards 3' end of mRNA, repeat steps to 1-3
stop codons (3) UAA, UAG, UGA
steps of translation Termination release factors bind when stop codon in A site, peptidyl transferase adds H2O to C-terminus of peptide, mRNA released and subunits dissociate
main differences in eukaryote translation initiation more initiation factors, tRNAimet not , initiation complex forms at 5' end of mRNA and scans until 1st AUG
steps in Eukaryote initiation preinitiation complex forms, scans until 1st AUG, elf-2 released and 60S binds, aminoacyl-tRNA binds A site
differences in eukaryote translation elongation proteins have different names, single release factor (eRF1) recognizes all stop codons
Kozak Sequence optimal sequence surrounding start codon (GCC(G/A)CCAUGG)
Codon triplet of nucleotides that specifies an amino acid
suppressor mutations cancel effects of original mutations
reading frame linear sequence of codons in mRNA determined by positioning on ribosome
Partial vs complete degeneracy swapping just among purines/pyrimidines vs swapping any nucleotide
wobble hypothesis 3rd position less stringent, tRNAs capable of binding more than 1 codon
conservative substitution similar amino acids differ by only 1 base, mutations will substitute similar aa that may not change functional properties
characteristics of genetic code triplet, nonoverlapping, comma-free, degenerate, ordered degeneracy, start and stops (punctuated), universal
induced mutation result from influence of artificial factors
somatic mutations affect descendants of that cell, not progeny (impact greater in embryonic development)
chromosomal aberration changes in chromosome number or arrangement (ex. Down syndrome, cancer)
gene mutation changes in DNA sequence, source of most new alleles
effects of mutation at amino acid level silent (no change), neutral (similar), missense (effects), non-sense (stop), frameshift
suppressor mutation second, DIFFERENT mutation that suppresses effect of 1st
conditional mutation lethal/inactive in restrictive environment, viable/active in permissive
auxotroph unable to synthesize essential metabolite
suppressor sensitive viable in presence of suppressor
tautomeric shift movement of hydrogen atoms between common and rare positions on a base (exist briefly)
4 mutations induced by chemicals alkylating agents, base analogs, oxidative deamination, intercalating agents
mutagenic potential # test colonies - # control colonies (related to tumor forming potential)
DNA Repair mechanisms photo-reactivation, excision, mismatch, post-replication, double-strand break
Xeroderma Pigmentosum recessive disorder in repair enzymes - hyper-sensitive to UV light, risk of skin cancer
DNA recombination Genetic exchange at equivalent positions along two chromosomes with extensive DNA sequence homology
size of Bacteriophage T4 dsDNA genome 168000bp, 150 genes
bacteriophage T4 life cycle 2min - mRNA synthesis, 6min -DNA replication, 14min – assembly begins, 17 min- assembled phage, 25 min – host cell lysis/progeny released
size of bacteriophage lambda genome 48,502 bp, 50 genes
prophage integrated state of the ג chromosome
lysogenic state phage proteins not expressed
size of single bacterial chromosome (Escherichia coli) 4.64 Million nucleotides, 4,377 genes
plasmid replicate independently of bacterial chromosome, can transfer between bacteria, present in single or multiple copies
mechanisms of gene transfer in bacteria (3) transformation, conjugation, transduction
test for gene transfer mechanism with barrier (cannot be conjugation), DNase addition (must be transduction)
heteroduplex DNA each strand contains different alleles
contransformation frequencies measured to calculate map distances
sexduction F1 x F- mating
generalized transduction random fragment of bacterial DNA is packaged in phage head in place of phage chromosome and recombines with recipient chromosome
specialized transduction phage chromosome packaged in phage head contains some bacterial DNA arising from a recombination event between phage and bacterial DNA (more common)
Resistance transfer factor (RTF) encodes genes required for conjugation
R-Determinant encodes genes providing antiobiotic resistance
composite transposons two insertion sequences insert next to each other
tnpA, tnpR, bla, res transposase: catalyzes insertion, resolvase/repressor: involved in recombination, β-lactamase: breaks down ampicillin, resolution site: recombination separation site
Transposons and Genome Organization Telomere maintenance, recombination resulting in deletions and duplications
non-replicative transposable elements IS, composite, Ac/Ds, P
Replicative transposable elements (DNA and RNA intermediate) DNA - noncomposite (Tn3), RNA - retrovirus-like and Retroposons
operon coordinately regulated units of genes with related functions (promoter, operator and structural genes)
patterns of gene expression (3) constitutive (always ON), inducible (default OFF), repressible (default ON)
lac operon constitutive mutants lac enzyme produced in presence or absence of lactose (lacI- or lacOc)
cis vs. trans acting factors cis - physically linked, trans - separate entities
levels of trp operon control repression (negative mechanism), attenuation
attenuation termination of mRNA synthesis (transcription), after initiation
post-transcriptional control of gene expression in bacteria (3) translation initiation efficiency, ribosome movement efficiency, mRNA processing and degradation
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