Chapter 4 (Notes) Bacterial Growth Flashcards
heterotrophy
organic nutrient
autotrophy
CO2 + inorganic energy source
microbial growth vs. cell division
microbial growth: populations of cells
cell division: individual cells
phototrophy
light absorption
lithotrophy
mineral oxidation
photoheterotroph
light + organic compounds
photoautotroph
light + CO2
use H2O to reduce CO2 - oxygenic photosynthesis
don’t use H2O to reduce CO2 - anoxygenic photosynthetic bacteria
chemoautotroph
chemicals + CO2
H, S, Fe, N, CO oxidizing bacteria
chemoheterotroph
chemicals + organic compounds
O2 final electron acceptor - animals, fungi, bacteria, protozoa
not O2 organic - fermentative
not O2 inorganic - electron transport chain
3 types of nutrients
micronutrients (trace)
macronutrients
macroioninc
micronutrients
Cu, Co, Mn, Fe, Ni
macronutrients
C, N, P, S, O, H
macroioninc nutrients
Ca, Mg, Na, Cl, Fe
3 fueling processes
CO2 fixation
autotrophy
heterotrophy
nutrient uptake types
N2 fixation, or assimilation/transport (NO3, NH3)
phosphorus assimilation
H2O
fuel/energy
ATP
reducing power (NADH, NADPH)
precursor metabolites (13)
building blocks
nt
FA
glycerol
sugars
aa
macromolecules
phospholipids
proteins
sterols
DNA/RNA
glycan
structures
cell membrane
replisome
DNA genome
ribosome
sacculus (peptidoglycan cell wall)
when is a membrane potential generated
when chemical energy is used to pump protons outside the cell
proton motive force
H+ gradient plus the charge difference from electrochemical potential
potential energy used to transport nutrients, drive flagellar rotation, and make ATP
how is ATP made
F1F0 ATP synthase
N2 makes up __% of the Earth’s atmosphere
79%
most organisms can’t use it
N2 fixation is done by prok with the enzyme…
nitrogenase
nitrogen-fixing bacteria free living in soil/H2O or symbiotic relationship with plants
