Deck 6: The Origin and Evolution of Life on Earth

A) fossils of the first organisms to introduce oxygen into the atmosphere
B) fossils of the first multicellular organisms
C) layers of sediment that once contained colonies of ancient microbes
D) fossils of the first eukaryotes

A) more than 3.5 billion years ago
B) exactly 3.5 billion years ago
C) less than 3.5 billion years ago
D) exactly 3.85 billion years ago

A) living organisms absorb only the most common carbon isotope
B) living organisms remove all carbon from rocks
C) living organisms absorb certain carbon isotopes more easily than others
D) carbon isotopes are found only in living organisms

A) are genetically very different
B) look very similar to the eye
C) are genetically identical
D) are genetically very similar

A) oxygen in the air
B) poop deposited on them by birds
C) photosynthesis
D) corals that live on their surfaces

A) at the branch between animals and plants
B) very close to the root
C) at the branch between Archaea and Eukarya
D) very far from the root

A) carbon-14
B) carbon-13
C) carbon-12
D) carbon-11

A) they are found in rocks from the Hadean Eon
B) it is not clear whether they are of biological or non-biological origin
C) the rocks they are found in are probably contaminated by terrestrial bacteria
D) they are too small to be of biological origin

A) living stromatolites
B) microfossils
C) zircons
D) protocorals

A) studies of Martian meteorites
B) studies of organisms living around deep-sea ocean vents
C) studies of the fossil record
D) laboratory simulations of conditions present on the early Earth

A) originated when the Earth formed 4.6 billion years ago
B) originated about 3.0 billion years ago
C) existed 3.85 billion years ago
D) existed before about 3.0 billion years ago and may well have existed before 3.5 billion years ago

A) an age of 3.5 billion years old
B) ages between 2.7 and 3.0 billion years old
C) ages between 3.2 and 3.5 billion years old
D) an age of 3.85 billion years old

A) must have appeared exactly 3.85 billion years ago
B) could have appeared as soon as the Earth formed, 4.6 billion years ago
C) could have appeared more than 3.85 billion years ago
D) must have appeared exactly 3.5 billion years ago

A) the first living organisms would have left absolutely no trace of their existence
B) life was planted on the Earth by an advanced civilization so there is no evidence in the geological record to find
C) the geological record does not extend back to the time that life originated
D) the oldest rocks are too deep inside the Earth for us to retrieve

A) 6 protons, 6 electrons, and 13 neutrons
B) 6 protons, 7 electrons, and 7 neutrons
C) 7 protons, 7 electrons, and 6 neutrons
D) 6 protons, 6 electrons, and 7 neutrons

A) 4.6 billion years ago
B) 3.5 billion years ago
C) 3.85 billion years ago
D) 4.0 billion years ago

A) isotopes other than carbon that also show ratios consistent with biological activity
B) microfossils within the rocks
C) DNA within the rocks
D) oxygen gas trapped within the rocks

A) DNA within the rocks
B) microfossils within the rocks
C) similar carbon isotope ratios in other rocks of comparable age
D) oxygen gas trapped within the rocks

A) existed before about 3.0 billion years ago and may well have existed before 3.5 billion years ago
B) originated about 3.0 billion years ago
C) existed 3.85 billion years ago
D) originated when the Earth formed 4.6 billion years ago

A) RNA world
B) bacterial world
C) protein world
D) extraterrestrial world

A) water
B) clay
C) concentrated amino acids
D) nucleic acids

A) impacts would have destroyed any life that appeared
B) water was not plentiful on land
C) there was no ozone layer to shield out harmful UV rays
D) organic materials were not present on the land

A) outgassing by volcanoes
B) molecules produced in the atmosphere by the action of lightning
C) molecules produced by chemical reactions near deep-sea ocean vents
D) molecules transported to the surface by impacts

A) contribution from impacts is not well understood
B) composition of the Earth's early atmosphere is not well known
C) amount of water that was present is not known
D) amount of UV radiation present from the Sun cannot be estimated

A) riboflavins
B) ribozomes
C) ribozymes
D) riboenzymes

A) 165 bases
B) only 5 bases
C) only 2 bases
D) 1967 bases

A) was planted on the Earth by an advanced civilization
B) originated close to deep-sea volcanic vents
C) originated in shallow ponds on the Earth's surface
D) was transported from another planet by meteorites

A) chemical reactions near the ocean surface
B) chemical reactions near deep-sea vents
C) material from space
D) all of the above

A) aerobic bacteria
B) anerobic bacteria
C) archaea living in both extreme and non-extreme environments
D) eukarya similar to ameoba

A) it is able to replicate at high temperatures found near deep-sea ocean vents
B) it is much simpler than DNA
C) in laboratory studies researchers have shown that it is able to catalyze its own replication
D) it is able to replicate using carbohydrates rather than proteins

A) simple life exists in comets
B) organic molecules can form in space and survive the passage through the Earth's atmosphere
C) organic molecules are completely absent in comet dust so impacts could not have made a significant contribution the organic material present on the early Earth
D) impacts must have been the only source of organic material present on the early Earth

A) proteins and nucleic acids probably looked very different before the origin of life
B) nucleic acids cannot replicate without proteins, and proteins cannot be made without nucleic acids
C) early proteins and nucleic acids were very similar to each other
D) proteins and nucleic acids are always present together at the same time

A) carbon dioxide (CO₂) and nitrogen (N₂)
B) carbonates (CO₃^-) and nitrates (NO₃^-)
C) methane (CH₄) and ammonia (NH₃)
D) carbon and nitrogen atoms

A) changed gradually into RNA
B) stayed the same
C) became gradually less complex
D) became gradually more complex

A) it is able to replicate using carbohydrates rather than proteins
B) it is far to complex to have been the first self-replicating molecule
C) it is able to replicate at high temperatures found near deep ocean vents
D) laboratory have shown that it is able to catalyze its own replication

A) a simple carbohydrate
B) DNA
C) a simple protein
D) RNA

A) on the surfaces of clays or other minerals
B) deep within the earth
C) in the atmosphere
D) in space and then transported to the Earth in meteorites

A) they are the only types of material monomers will stick to
B) they bring monomers close together, allowing them to react with each other
C) they are very common on the Earth
D) clays are made of biological polymers

A) are genetically very similar
B) are genetically very different
C) look very similar to the eye
D) are genetically identical

A) it is the theory that best fits the available data
B) because we have been able to create Life in the laboratory
C) because it was written down in ancient scriptures
D) because the other theories have been shown to be incorrect

A) very likely
B) certain
C) impossible
D) very unlikely

A) water
B) clay
C) lipids
D) nucleic acids

A) only cells can replicate
B) cell walls prevent heat from escaping
C) cells help to protect fragile biological molecules from the outside environment
D) biological reactions can occur only within cells

A) naturism
B) panspermia
C) intelligent design
D) chemical evolution

A) intelligent design
B) naturism
C) panspermia
D) chemical evolution

A) the biochemistry of Martian life is very different than life on Earth
B) the biochemistry of Martian life is very similar to life on Earth
C) Martian life shows evidence for natural selection
D) Martian life is cellular

A) very unlikely but not impossible
B) impossible
C) certain
D) very likely

A) single-celled eukaryotes
B) multicellular eukaryotes
C) single-celled prokaryotes
D) multicellular prokaryotes

A) being lasted from the parent planet
B) inside the meteorite with very little water present
C) long enough in space to make the journey to Earth
D) the impact onto the Earth's surface

A) the bases that make up DNA became much more common
B) DNA is far more stable than RNA
C) DNA can catalyze its own replication
D) the double helix of DNA is better able to correct errors in replication

A) sexually
B) symbiotically
C) aerobically
D) anaerobically

A) panspermia
B) intelligent design
C) naturism
D) chemical evolution

A) Mars only
B) All terrestrial planets
C) The Moon and Mars
D) The Moon only

A) chemoheterotrophs
B) photoautotrophs
C) photoheterotrophs
D) chemoautotrophs

A) purple and green sulfur bacteria
B) trilobites
C) cyanobacteria
D) stromatolites

A) a rate that slowly decreases with time
B) a constant rate
C) an exponential rate
D) a rate that slowly increases with time

A) cell walls prevent heat from escaping
B) cells concentrate molecules together so they can react more easily
C) only cells can replicate
D) biological reactions can occur only within cells

A) impossible
B) very likely
C) certain
D) possible

A) naturism
B) intelligent design
C) panspermia
D) chemical evolution

A) 545 million years
B) 360 million years
C) 2 billion years
D) 3.5 billion years

A) great oxidation event
B) great oxygen crisis
C) great oxygenation event
D) great photosynthetic event

A) the amount of oxygen in the Earth's atmosphere has remained constant throughout its history
B) Earth's atmosphere contained much more oxygen in the past compared to today
C) there was no oxygen in the Earth's atmosphere at that time
D) Earth's atmosphere contained much less oxygen in the past compared to today

A) the carbon dioxide cycle started to operate for the first time
B) carbon-rich meteorites impacted the Earth
C) the first carbon-based life appeared
D) land was covered with dense forests with the appearance of the first insects and amphibians

A) the decomposition of dead organisms
B) plants
C) cyanobacteria
D) oxidation reactions

A) evolution of life on Earth is no longer occurring
B) such an explosion can occur only for simple organisms and not complex ones
C) there are no more ecological niches available to allow this to happen
D) of the widespread presence of efficient predators that make it much more difficult for entirely new organisms to appear

A) prokaryotes are seen incorporating into cells today
B) organelles float around independently inside eukaryotic cells
C) the DNA inside organelles is not made of the same four bases as the DNA in the host cells
D) they have their own DNA and reproduce independently of the host cell

A) the first oxygen-producing bacteria appeared
B) the first dinosaurs appeared
C) early humans first appeared
D) an explosion of genetic diversity appeared, leading to the appearance of the first animals

A) Bacteria
B) Prokaryotes
C) Archaea
D) Eukarya

A) 475 million years ago
B) 65 million years ago
C) 360 million years ago
D) 545 million years ago

A) 545 million years ago
B) 360 million years ago
C) 65 million years ago
D) 475 million years ago

A) 4.6 billion years ago
B) around 3.5 billion years ago
C) 4.0 billion years ago
D) at least 2.1 billion years ago or perhaps even earlier

A) appearance of multicellular organisms
B) development of photosynthesis
C) oceans being overcrowded
D) development of the ozone layer

A) 2.1 billion years ago
B) 545 million years ago
C) 360 million years ago
D) 65 million years ago

A) viral
B) sexual
C) symbiotic
D) parasitic

A) 4.6 billion years ago
B) 3.5 billion years ago
C) 4.0 billion years ago
D) 2.4 billion years ago

A) the DNA inside organelles is not made of the same four bases as the DNA in the host cells
B) organelles float around independently inside eukaryotic cells
C) prokaryotes are seen incorporating into cells today
D) organelles are very similar to present-day bacteria, suggesting a common ancestor

A) The Cretaceous Period
B) The Carboniferous Period
C) The Cambrian Period
D) The Archaean Eon

A) the extinction of older anaerobic life as oxygen built up in the atmosphere
B) the time period before the development of the ozone layer
C) a period when evolution accelerated so rapidly that there was insufficient oxygen available
D) the destruction of oxygen in the early atmosphere

A) protocells
B) prokaryotes only
C) multicellular organisms
D) single-celled organisms