88 ■ CHAPTER 05 How Cells Work
CELLS
and each carbon atom is released into the envi-
ronment in a molecule of CO 2 , with water (H 2 O)
as a by-product. Thus, cellular respiration is the
reciprocal process of photosynthesis, as illus-
trated earlier, in Figure 5.2. In most eukaryotes,
cellular respiration is a multistep process that
occurs in the cell’s mitochondria (Figure 5.10).
Cellular respiration is the main way that animal
cells, which do not perform photosynthesis,
obtain energy. We digest glucose from food
sources; break it down into carbon dioxide,
hydrogen, and electrons; and then process those
captured electrons for energy.
Simply put, cellular respiration consists of
three stages: glycolysis, the Krebs cycle, and
oxidative phosphorylation (Figure 5.11). The
first stage, glycolysis, takes place in the cyto-
plasm of the cell. During glycolysis, sugars
(mainly glucose) are split to make a three-carbon
compound called pyruvate. This process results
in two useful molecules of ATP and two mole-
cules of NADH for each glucose molecule that
is split (Figure 5.11, top left). In other words,
glycolysis converts some of the chemical energy
of glucose into the chemical energy of NADH
and ATP.
From an evolutionary standpoint, glycoly-
sis was probably the earliest means of produc-
ing ATP from food molecules, and it is still
the primary means of energy production in
many prokaryotes, including some of Rowe’s
microbes. However, because glucose is only
partially broken down through this process, the
Into the Light,
Part 2
As Spormann was unraveling the mechanisms
of how electron-eating life works, Rowe’s pros-
pecting trip to Catalina uncovered more species
of rock eaters (Figure 5.9). From her tanks,
Rowe identified 30 new varieties of microbes
sucking electrons from the electrodes. She was
even able to grow a few of them on plates in
the laboratory, using minerals like sulfur and
iron as electron sources for the microbes to
munch. Not all the species relied exclusively on
electrons as a food source; that is, they didn’t
just live off mineral sediments. Like eukary-
otic cells, most microbial cells use the tradi-
tional route of cellular respiration for obtaining
energy, converting sugars into energy through
catabolic reactions.
During cellular respiration, the carbon-
carbon bonds in glucose molecules are broken,
Figure 5.9
Sediment containing rock eaters,
collected off the coast of Santa
Catalina Island
Outer Matrix
membrane
Inner
membrane
Intermembrane
space
Mitochondrion
Figure 5.10
Mitochondria are the site of cellular
respiration in eukaryotes