biol 189 exam 3 review

pyrimidines

Cytosine and Thymine

gene expression in eukaryotes

DNA availability, transcription factor availability, mRNA processing, mRNA transport from nucleus, RNA degradation, protein processing and degradation

1. DNA availability

DNA can be tightly bound to histone proteins that can prevent gene expression. Chemical modifications of histones can open up (or close off) DNA for transcription

AFTER DUPLICATION

DNA doesn't condense into 2 visible sister chromatids until the first phase of mitosis (prophase)

X-linked recessive

Disorder = Hemophilia A - Males more likely affected (hemizygous) - Females often carriers but no display of phenotype

mutagens

a cause of mutations; any external agent that induces mutations such as radiation, chemicals, infectious agents

cancer

a class of diseases characterized by malignant cell growth in the body; can overwhelm normal function of organ systems and result in death

theory of evolution

a comprehensive explanation of some aspect of nature that is supported by a vast body of evidence

autosomal dominant

a disorder expressed with 1 or 2 more copies of disease-causing allele

ophioglossum reticulatum

a fern with ~1440 chromosomes

transcription

a gene's DNA sequence is rewritten into a mRNA molecule in the nucleus

lac operon

a group of genes that function to break down lactose sugar but are expressed only in the presence of lactose sugar

species

a group of organisms that can successfully interbreed and produce viable offspring

tumor

a mass of cells undergoing uncontrolled cell division

semi-conservative replication

every new DNA molecule is half old DNA and half new DNA; old strands are templates for DNA polymerase to build the complementary strand

model organism

garden pea plant to study patterns of heredity

evolution

genetic changes in population over many generations

incomplete dominance

heterozygote has intermediate phenotype - Ex: Rr phenotype is pink bc neither red nor white alleles are dominant, resulting in a blended phenotype

chromosomes

highly condensed (compacted) chromatin; found only during active cell division/mitosis

viral replication: synthesis

host cell is hijacked to produce millions of copies of the viral genome and viral proteins

viral replication: release

host cell releases the newly formed viral particles (some viruses kill host cell during release [lysis] others released by exocytosis [vesicles])

somatic cell cycle phases

interphase and mitosis

6. Protein processing and degradation

just like mRNA, proteins can be regulated at the level of production and degradation. Some proteins get degraded as they are transcribed while others can be maintained long after production.

malignant tumor

lack a capsule and can enter in circulatory systems and seed new regions of the body

viable offspring

offspring that are healthy and also capable of reproduction

splicing

process of removing introns and connecting exons from pre-RNA to form mature mRNA

Hardy-Weinberg Equation

p2 + 2pq + q2 = 1

sex chromosome

pair 23; determines biological sex of a person; XX = FEMALE, XY = MALE

autosomes

pairs 1-22; contain genetic instructions of general life processes

silent mutations

point mutations that do not change protein's amino acid sequence; tolerated in wobble position of a codon

sexual reproduction

requires the combination of genetic material from two individual organisms; when 2 gametes fuse to make new individual offspring and next generation of organism; need to find mate, 50% of each parent's genes, increases genetic diversity

introns

segments removed from pre-mRNA- trash RNA

true-breeding or pure-breeding plants

self-fertilization yields offspring with same seed color as parent plant; Mendel used these plants to produce monohybrids

termination in translation

stop codons mark protein ends; protein releases factors bind to stop codons and ribosomes release from mRNA

cytokinesis

the cytoplasm is split between new cells then separated with new cell membrane

sex-linked traits

traits dictated by genes on sex chromosomes; disproportionately affect one sex more than the other

benign tumor

uncontrolled cell division contained in a tough capsule (size limited and does not spread)

lysogenic phase of bacteriophage

viral genome incorporated into host genome aka prophage; stressful condition can cause translation into lytic phase

viral replication: assembly

viral particles assemble and genetic information moves inside

viral replication: attachment

virus binds to host cell surface receptors

viral replication: penetration

virus genome enters the host cell (phagocytosis, injection)

what is a gene?

a segment of DNA that contains instructions to make a specific protein or RNA molecule

autosomal dominant pedigree

affected individual appear in every generation - no specific sex

first key principle of evolution: common descent with modification

all life on earth began with the universal common ancestor = first living cell capable of reproduction

what multicellular eukaryotic organisms sexually reproduce?

all mammals, most birds, most reptiles, fish, flowering plants

what is a genome?

all of the DNA inside of a cell

interphase

bulk of a cell's life cycle will be spent in this phase; has 3 sub-phases (gap 1, synthesis [where DNA is replicated], gap 2)

frameshift mutation

cause the reading frame for the protein to be altered

polygenic trait

controlled by more than one gene (skin, eye, hair color depend on multiple genes for phenotype determination)

monohybrid crosses

crosses focused on only one trait in which Mendel crossed thousands of true-breeding plants

large-scale chromosome mutation examples

deletion, duplication, inversion, insertion, translocation

recessive allele

denoted by lowercase letters

dominant allele

denoted with capital letters

Hardy-Weinberg equilibrium

determines if evolution is occurring (change in allele and genotype frequencies)

allele

different forms of a gene

Mendel's Law of Independent Assortment

different genes separate independently/randomly during gamete formation in Metaphase I

Gregor Mendel (1822-1884)

discovered fundamental rules of heredity in diploid organisms (the mechanisms of passing traits or genes from parents to their offspring

Franklin, Gosling, Wilkins (1952)

discovered the helix shape, the size of a helix turn, how many base pairs per turn (10), and phosphate groups outside the helix through X-RAY CRYSTALLOGRAPHY

cystic fibrosis

disease caused by a genetic mutation in one transmembrane protein gene and often affects the lungs and mucous membranes; symptoms only apparent in those carrying 2 mutated alleles

cytokinesis in animal cells

- cleavage furrow, cells pinch off

diploid

2 sets of chromosomes; most sexually reproducing organisms

allele frequency

# specific allele / all alleles in gene pool

homozygous dominant

(YY) 2 copies of dominant allele

heterozygous

(Yy) 1 dominant 1 recessive

homozygous recessive

(yy) 2 copies of recessive allele

Lamarck (1800s)

- Animals inherit characters from their parents - Use or disuse of a structure or organ can cause it to enlarge or shrink in successive generations

Georges Cuvier (1769-1832)

- claimed extinction is a fact - periodic catastrophes led to organisms going away forever

X-linked traits

- Ex: red-green color blindness - proteins in cone cells of the eye are involved in color perception - males affected more b/c only one X copy

conclusion of Mendel's monohybrid crosses

- F1 generation always 100% one phenotype - F2 always had 3:1 phenotypic ratio - heritable factors came in pair and some traits were able to dominate others

cell theory

- all cells come form pre-existing cells - cells reproduce by dividing

transfer RNA

- carry specific amino acids to the ribosome - one end binds to specific amino acid - other end has anticodon that is complementary to codon

structure of DNA

- double helix - rails = sugar-phosphate backbone - rungs = paired nitrogenous bases with hydrogen bonds - complementary base pairing - anti-parallel

when a cell cycle goes wrong...

- if DNA mutations are not eliminated, it can lead to tumors then cancer

natural selection

- in nature, if breeding is unrestrained = struggle for survival

why is genetic diversity good?

- increased through sexual reproduction - high genetic diversity = evolution (ability to adapt to different/changing environments) - ability to adapt increases long-term survival - asexual organisms at greater risk of extinction due to reduced genetic diversity and changing environments

parts of Mendel's experimental design using the pea plant

- noticed patterns of specific traits from parent to offspring - performed controlled crosses by transferring pollen (sperm) from plants to flowers (eggs) of other plants

metaphase of mitosis

- nuclear membrane has completely disintegrated - microtubules attach to sister chromatids - form mitotic spindle (cage-like structure) - 46 chromosomes pushed and pulled to line up single file at metaphase plate (middle)

why are pea plants a great genetic model organism?

- sexually reproducing - self-pollinators - grow fast, easy to maintain, produce many offspring

telophase of mitosis

- spindle fiber microtubules begin to disintegrate - 2 nuclear membranes (one cell, 2 nuclei) - chromosomes decondense into chromatin - ANIMAL CELLS: 2 sets of protein form at midline

how to read a pedigree

- squares = males - circles = females - horizontal lines between 2 shapes = reproductive partnerships - vertical lines = offspring of specific partnership - filled shape = phenotype is seen - open shape = phenotype is not seen - half-filled shape = carrier but trait is not expressed - ? = phenotype unknown

cell cycle checkpoints

- the cell ensures it is ready to progress to the next phase (G1, S, G2, Mitosis) - failure of a check point results in apoptosis

X-chromosome inactivation

- to balance simultaneous gene expression, one X chromosome is turned off - Ex: orange/black fur in cats

James Hutton and Charles Lyell (geologists)

- uniformitarianism: forces that molded the planet today molded throughout history; slow continuous changes over long periods of time

cytokinesis in plant cells

- vesicles with cell wall sent to middle between nuclei, then fuse until cell wall is established

Thomas Robert Malthus (1798)

- wrote "An Essay on the Principle of Population as it effects The Future Improvement of Society" - human population theory - struggle for existence - humans produced more offspring than can survive

prophase of mitosis

-DNA condensed into chromosomes - centrosome copies move to the poles and synthesize microtubule spindle fibers -nuclear membrane disintegrates - spindle fibers extend and attach to centromeres of chromosomes

haploid

1 set of chromosomes; asexually reproducing organisms and gametes; binary fission (asexual) and meiosis (gamete formation)

how pre-mRNA is processed in eukaryotes:

1. add mRNA cap (modified nucleotide that serves as recognition signal for ribosome) 2. add poly-A tail (100-200 As protects mRNA from degradation in cytoplasm) 3. mRNA splicing

dihybrid cross

Mendel found new phenotypic rations in F2 = 9:3:3:1

what is Chargaff's rule?

Adenine always equals/pairs with Thymine; Cytosine always equals/pairs with Guanine

purines

Adenine and Guanine

chromatin

DNA is wrapped around histone proteins; loose configuration (allows for easy gene expression) and common configuration (when cell is not undergoing cell division)

naked DNA

DNA not associated with histones or histone-like proteins; found in active gene expression

binary fission

DNA replicates and attaches to the cell membrane of a parent cell that contains one chromosome, then membrane growth between the two points moves the DNA molecules away to form a new cell wall resulting in two daughter cells that are identical to the original

S phase of interphase

DNA replication - results in 2 identical sister chromatids attached by protein centromere

operator

DNA sequence between promoter and protein-coding genes; serves as regulatory region

what is the central dogma of biology?

DNA to RNA to proteins

what are the possible gametes from F1?

FOIL: first, outer, inner, last (R r Y y)

Darwin's ideas

On the Origin of Species (1859)

traits Mendel studied

Parental (P), 2 offspring generations (F1 and F2)

elongation in transcription

RNA polymerase reads the DNA template and adds complementary RNA nucleotides to the growing molecule as it moves down the gene (think nitrogenous base pairings!)

repressor proteins

WITH NO LACTOSE...bind to the operator and physically stops RNA polymerase and operon gene expression

macroevolution

accumulation of microevolutionary changes over millions of years resulting in reproductive isolation resulting in the formation of new species

how do prokaryotes divide?

binary fission

wobble position

change in 3rd base of the codon; allows mutations to occur without effects in the protein

definition of evolution

change in genetic makeup of a population of organisms over many generations

microevolution

changes in allele frequencies/traits in a population over short evolutionary time (a few generations)

homologous chromosomes

chromosome pairs that have the same genes in the same location

operon

clustered group of genes related to a specific function that can be turned on or off as needed; contains promoter, operator, operon genes

operon genes

code the required proteins

Alfred Russel Wallace

conducted field studies of species diversity in the Amazon then Indonesia; developed identical theory as Darwin, but Darwin received credit

5. RNA degradation

enzymes in cell actively degrade RNA. mRNA can be chemically modified which can change its "lifespan" and the likelihood that a transcript will be made into a protein or not.

phenotype

expressed traits (physical appearance); determined by the genotype

G2 of interphase

extra growth and preparation for mitosis

Darwin's concepts leading to theory of evolution

gradualism (new species result from ancestral species undergoing slow constant changes over long periods of time) and the galapagos finches (all different species came from a single ancestor species from S. America)

cell division

growth and development, wound repair, tissue regeneration, microbial fission/budding

what enzymes are involved in DNA replication

helicase (unwinds and unzips DNA), DNA polymerase (assembles and proofreads new DNA strands), and ligase

selective pressures

how strongly the environment selects for a particular trait; any component of the living and non-living environment that results in differences in survival and reproduction

4. mRNA transport from nucleus

if mRNA is not specifically transported from the nucleus, it will not become a protein

karyotype

image showing all of an individual organism's chromosomes; typical karyotype has 46 chromosomes (23 pairs)

why are codons 3 bases?

in order to provide proteins with a huge variety of molecular interactions (h-bonds, hydrophilic, hydrophobic, charged, uncharged); needs to specify at least 20 unique amino acids with only 4 bases

where do inactived x-chromosomes stay?

in the condensed chromosome form called the Barr body in the nucleus

where does translation occur?

in the cytoplasm! or associated with the rough endoplasmic reticulum (bound ribosomes)

polysome

increase protein synthesis efficiency with multiple ribosomes on a single mRNA

Mendel's Law of Segregation

individual alleles separate during gamete formation such that each gamete receives only 1 copy of each gene; through meiosis

3 main steps of transcription

initiation, elongation, termination

3 steps of translation (in cytoplasm!)

initiation, elongation, termination

initiation in translation

mRNA cap helps mRNA associate with ribosomes

translation

mRNA molecule leaves the nucleus and enters a RIBOSOME (free or bound) where the mRNA codes for the specific amino acids in a polypeptide chain

microtubules

made of tubulin proteins; dynamic movements of chromosomes and cellular components during mitosis is dependent on microtubules

anaphase of mitosis

microtubules begin to pull sister chromatids apart toward opposite poles of cell; cell membrane elongates

how do eukaryotes divide?

mitosis (occurs in body cells [somatic cells] in multicellular organisms

polyallelic trait

more than two alleles (human blood type)

eukaryotes

multiple linear chromosomes

polypoid

multiple sets of chromosomes

five agents of evolution

mutation, gene flow, genetic drift, sexual selection, natural selection

how do prokaryotes evolve if binary fission makes cells that are identical copies?

mutations and horizontal gene transfer

what can result in aneuploidy?

nondisjunction that violates Mendel's law of segregation

G1 of interphase

normal cell functions and growth

ploidy

number of sets of chromosomes in a cell or an organism

centrosomes

organelle that makes microtubules for mitosis

apoptosis

programmed cell death; regulated by a class of enzymes called caspases (exist in every cell awaiting an activation signal)

initiation in transcription

promoter region; where the gene starts and what strand to use as a template; transcription factors (proteins) guide RNA polymerase to template DNA strand at the correct location

4 phases of mitosis

prophase, metaphase, anaphase, telophase

prions

protein-based infectious particles aka zombie proteins; misfolded proteins; results in massive accumulation of misfolded proteins that turns into cell death. ex: mad cow disease from eating nervous tissue of previous infected cows

2. Transcription factor availability

proteins that bind to promoter regions of DNA and help direct RNA polymerase to gene

recombination/crossing over

random process during prophase I that results in 2 parental chromatids and 2 recombinant chromatids (may mix up linked parental traits); ALSO more likely to occur spaced far apart on the same chromosome

lytic phase of bacteriophage

rapid viral replication which causes infected cells to die; massive release of new viral particles into the organism/environment

horizontal gene transfer

receiving genes from something other than parental cells (mechanisms in prokaryotes: transformation, conjugation, transduction)

3. mRNA processing (alternative splicing)

removal of certain introns/ exons can have dramatic effects on downstream protein products (see earlier slide)

virus function

replication & propagation - make more of itself and infect new hosts; there are 5 stages...

asexual reproduction

reproduction without the involvement of another organism; no need to find mate, maintain good genes, and reduced genetic variety

elongation in transation

ribosome moves mRNA down one codon after Met, next codon is read, tRNA enters, ribosome makes covalent peptide bond between amino acids, tRNA exits, ribosome moves down one codon, etc.

exons

segments joined together to make mature mRNA

prokaryotes

single circular chromosome

promoter

site where RNA polymerase binds

plasmids

small circles of DNA that contains one or a few specialized genes; gets replicated with main bacterial chromosome during binary fission

mitosis

somatic cell division; cell actively divides into 2 cells

2nd key principle of evolution: natural selection

some individuals in a population will have specific combinations of alleles better suited for a particular environment at that particular time = increased chance of surviving and reproducing

origins of replication

specific DNA sequences that signal where to begin replication

start codon

specific codon that starts amino acid incorporation (in eukaryotes...start codon is AUG [methionine] so all polypeptide sequences start with Met as first amino acid)

termination in transcription

specific termination sequence indicates end of gene; RNA polymerase releases from the DNA when it recognizes the sequence, then mRNA molecule is released

gametes

sperm and egg

late prophase of mitosis

spindle fiber microtubules become attached to the sister chromatids of each chromosome

Thomas Hunt Morgan

studied fruit fly traits and his work led to our understanding of chromosomes as hereditary unites (each chromosome carries many genes); realized that specific crosses in flies produced higher proportions of recombinant offspring

what happens when the ribosome reads the mRNA codon?

tRNA enters ribosome, codon-anticodon base pairing, new amino acid is covalently bound to previously added amino acid

reproduction

the biological process by which individual organisms (offspring) are produced from parents; also called vertical gene transfer

what are nucleic acids?

the information-bearing molecules of all life on earth (genetic material); polymers made up of nucleotide monomers

IF genes are located on the same chromosome...

they are inherited together! therefore, they do not follow the Law of Independent Assortment which leads to unexpected phenotypic ratios

codon

three bases are read at a time by a ribosome; specifies a specific amino acid to be added to the polypeptide

vaccines

to combat viruses, you can train the immune system to recognize the pathogen before actual infection occurs. otherwise, supportive therapy/waiting for the immune system recognizes the virus to create a natural immune response

genetic linkage

two genes are closely associated on the same chromosome and do not assort independently

mutations

unintended changes in the cell's DNA sequence; can affect a single DNA base, few bases, or large chromosome proportions; can cause diseases; silent or harmful; mutations are rarely beneficial

Watson, Crick (1953)

used Chargaff's rule and X-ray crystallography to determine molecular structure of DNA; purine + pyrimidine pairs

test cross

used to determine if the dominant parent is homozygous or heterozygous dominant; dominant trait crossed with true breeding recessive trait

viruses

very small protein shells that contain genetic material made of either DNA or RNA

punnett squares

visual representation of crosses; demonstrate potential offspring genotypes and phenotypes; used to determine likelihood (%) of specific genotypes/phenotypes that could result from specific genetic crosses

codominance

when 2 different alleles can be expressed simultaneously in the phenotype - Ex: ABO blood typing

subspecies

when microevolutionary phenotypic changes do not result in reproductive isolation