Midterm Bio Review PDF

Summary

This document provides a review of biological concepts, including microscopy techniques, chemical properties of biological molecules, and basic biochemistry.

Full Transcript

Microscopy

Approx. size ranges of prokaryotic and eukaryotic cells (μm)

○ prokaryotic = 0.1 - 10 μm

○ eukaryotic 10-100 (animal 10-30; plant 10-100) μm

Minimum object size visible to human eye

○ 100 μm (0.1mm)

The criteria of an effective microscope

○ Magnification - increase in size

○ Resolution and LoR

Resolution - distinguish between 2 objects.

LoR - smallest distance apart to distinguish 2 separate objects

(smaller, stronger)

○ Contrast - difference between object and background

Differences Between Optical and Electron Microscopes

○ Magnification: Optical: Up to 1000x to 2000x. Electron: Up to 1,000,000x

or more.

○ Limit of Resolution: Optical: ~0.2 μm. Electron: ~0.2 nm.

○ Source of Illumination: Optical: Beam of light. Electron: Electron beams.

Confocal microscope

○ You can pick a focal plane of the specimen, making desired object clearer.
 Wavelength

○ longer wavelength, lower energy

○ shorter wavelength, higher energy

Visible spectrum: 380 - 740 nm

Fluorescence: absorb light -> emit light at lower energy (longer wavelength)

fluorescein isothiocyanate (FITC) - 495nm -> 519 nm

Chemistry of the Cell

Aldoses vs. Ketoses

○ Aldose; outside

○ Ketose; inside

Acid vs. Base

○ acid = proton donor & ph < 7

○ base = proton acceptor or releases hydroxide ions (OH-) & ph > 7

The periodic table

○ metals and non-metals:

metal = group 1-2; cation (positive +); lose electrons

nonmetal = group 15-17; anion (negative -); gain electrons

Electron Shell Capacity

1st = 2 electrons. subsequent shells = 8 electrons.
 Covalent vs. Ionic Bonds

○ Non-polar Covalent: 0 - 0.4 (Equal sharing of electrons)

○ Polar Covalent: 0.5 - 1.8 (Shared unequally between non-metals)

○ Ionic: 1.9-2.3 (Completely Transferred)

Fluorine - 3.98 electronegativity

Hydrogen bonds:

○ Oxygen (O) or Nitrogen (N) partial negative charge.

○ Hydrogen (H) partial positive charge.

Special properties of water

○ pH = 7

○ density of ice relative to water = ice is less dense because bonds spread out

○ most dense at 4°C

○ high surface tension

○ hydrophilic solutes

Macromolecules

Polymerization vs. De-polymerization

○ Polymerization: Small molecules (monomers) combine chemically to

produce long chains (polymers). Needs energy

Anabolic process - polymer growth

Condensation - produces water
 ○ De-polymerization: Breaking down of polymers into monomers.

Energetically favorable. Spontaneous.

Catabolic process - polymer breaks down

Hydrolysis - consumes water

Structural Isomers

○ Same chemical formula - Different atom arrangement/structure.

α- and β-Glucose Isomers

○ Alpha glucose - parallel hydroxyl groups

○ Beta glucose - hydroxyl group mirrored to other side

Glucose Disaccharides

○ Maltose = glucose + glucose

○ Lactose = galactose + glucose

○ Sucrose = glucose + fructose

D vs. L sugar enantiomers

○ D (dexter) or L (laevus) - naturally found in D form

Glycogen

○ Branched

○ Cytoplasm (liver and muscle cells)

○ Rapidly catabolized if energy needed

Cellulose

○ Unbranched

○ β - 1,4 glycosidic bonds
 Lipids

○ Don’t form polymers

○ Hydrophobic

○ Insoluble in aqueous solutions

Phospholipid Bilayer

○ Head - phosphate group; hydrophilic; polar

○ 2 Tails - fatty acid; hydrophobic

○ Bound to a glycerol backbone

Steroids

○ 4 rings carbon structure

○ Influence membrane fluidity

○ Signaling molecules (cholesterol, estrogen, testosterone, cortisol)

Cholesterol

○ Major sterol in animal cells

○ Stiffens phospholipid bilayer

○ Connects to adjacent polar heads

○ Reduces permeability of small water-soluble molecules

Fatty Acids

○ Saturated
 Can be stacked

Higher melting point

Solid at room temp.

○ Un-saturated

Loose tails (has “kinks” in hydrocarbon chain)

Reduced compressibility

Liquid at room temp.

Proteins

○ Primary - amino acid sequence

○ Secondary - polypeptide backbone atomic interactions

α-helices

β-pleated sheets

○ Tertiary - amino acid side chain interactions

○ Quaternary - multiple peptide chain interactions

Nucleotides vs. nucleosides

○ Nucleotide - all parts (includes phosphate group)

○ Nucleoside - nitrogenous base & sugar (NO phosphate group)

Deoxyribose vs. Ribose sugars

○ glycosidic bonds at carbons 1, 2, 3, and 5.

○ Ribose has 2 hydroxyl groups
 ○ Deoxy has 1 hydroxyl group

5 Nitrogenous Bases

○ Pyrimidines (CTU) - 1 nitrogen-containing ring

Cytosine (C)

Thymine (T)

Uracil (U), found in RNA

○ Purines (AG) - 2 nitrogen-containing ring

Adenine (A)

Guanine (G)

Membrane Transport

Solutes with HIGH permeability

○ Small

○ Uncharged

○ Non-polar

Solutes with LOW permeability

○ Large

○ Charged (ions)

○ Polar

Sodium-Potassium Antiporter
 ○ 3 - Sodium (Na) goes in

○ 2 - Potassium (K) goes out

○ ATP is hydrolyzed; turned to ADP

○ Contributes to a NEGATIVE resting potential within the cell

Tonicity - Water flows from hypo to hyper

○ Hypotonic - low solute

○ Hypertonic - high solute

○ Isotonic - equal solute

Cell Tonicity

○ Animal Cell

Hypotonic - Lysed

Hypertonic - Shriveled

Isotonic - Normal

○ Plant Cell

Hypotonic - Turgid

Hypertonic - Plasmolyzed

Isotonic - Flaccid

Facilitated Diffusion (Proteins)

○ Transporter - bind solute and change direction

uniporter - single one-way

symporter - two lane one-way

anti-porter - two-way
 ○ Channel - always open or closed

Passive vs. Active Transport

○ Passive - down electrochemical gradient; no energy required

○ Active - AGAINST electrochemical gradient; requires energy

Diffusion - Passive movement down an electrochemical gradient

○ Osmosis - net movement of water; semi-permeable membrane

Aquaporins - channel proteins that facilitate osmosis

Endocytosis - stuff goes in the cell

○ Phagocytosis - eats stuff outside the cell

Phagocytic cells eat foreign particles; relies on pathogenic antibodies

and cell receptors

○ Pinocytosis - cellular drinking; invagination; small particles only (noob

endocytosis)

○ Receptor Mediated Endocytosis (RME) - macromolecules bind to receptors

on cell’s surface (pino but highly selective + extra steps)

Organelles

Rough E.R. - has ribosomes on the surface / undergoes protein modification /

continuous with nuclear membrane

Smooth E.R. - lipid / fat production
 Cytoskeleton

○ Intermediate Filaments - structural support

○ Microfilament - cell shape

○ Microtubules - inner cell transport, cell division, cell movement

Lysosome - breaks down stuff (using hydrolase)

○ pH - 5

○ Damaged organelles and food particles are degraded to recycle components

Peroxisome

○ produces hydrogen peroxide (H2O2)

○ Uses enzyme CATALASE for peroxidation catalysis

○ lipid oxidation

○ Important in liver and kidney cells

Nuclear envelope - holds nucleus

○ Nuclear pore - door for nucleus

○ Nuclear lamina - structural support for envelope

○ Outer membrane is continuous with Endoplasmic Reticulum

Nucleolus - ribosome biogenesis

Vesicles

○ Transport - transport cargo between organelles

○ Secretory - Golgi apparatus to plasma membrane out of the cell

○ Endocytic - endocytosis

Cytoplasm - contains everything outside the nucleus
 Cytosol - funny cell gel

Plasma Membrane - keeps stuff in the cell

○ Responds to signals with signaling proteins.

○ Carbohydrate groups are involved in cell signaling

Eukaryotic Cell Division

Central Dogma

○ DNA Transcription -> RNA Translation (mRNA) -> Protein

Centromere

○ Small ring that connects two haploid cells

Human Gamete Cell

○ 23 per haploid cell (sperm / egg)

Human Non-Gamete Cell

○ 46

Cell Cycle (Typically lasts ~24 hours

Cell Cycle Checkpoints:

Start Transition
 G2-to-M Transition

Metaphase to Anaphase

○ Interphase ~23 hours

G1 - end of mitosis

S - DNA Replication

G2 - End of Replication; start of Mitosis

○ Mitosis ~1 hour

Chromosomes separate

Cells divide

DNA Replication Enzymes / Proteins

○ dna helicase: unwinds dna (uses atp)

○ binding protein: helps stabilize dna

○ primase: makes rna primers to begin polymerase (5' to 3')

○ dna polymerase: makes 5' - 3' activity. goes along 3' - 5' strand. can remove

wrong nucleotides along 3' - 5'.

○ polymerase α: makes dna on lagging strands

○ polymerase δ: makes Okazaki fragments and replaces RNA primers

○ polymerase ε: makes leading strand

○ dna ligase: fills in lagging strands

Continuous vs. Discontinuous Synthesis

○ DNA polymerase ONLY synthesizes in 5’-to-3’

○ Lagging strand is called Okazaki fragments; filled in with ligase
 Replication Fork

○ Contains both leading and lagging strand

Origins of replication

○ Primase makes RNA primers (primase moves along 3’-to-5’)

Mitosis:

○ Prophase

chromosome condensing

mitotic spindle on ends

Centrosomes duplicate then move to ends of cell

○ Prometaphase

nuclear envelope no more

mitotic spindle attach to kinetochores

○ Metaphase

chromosomes align

○ Anaphase

splits chromosomes

○ Telophase

decondensation

split ends make nuclear envelopes each

contractile ring formation