Skip to 0 minutes and 3 seconds We think the Earth is about four-and-a-half billion years old and that life evolved on the planet roughly four billion years ago. This is such a massive, incomprehensible amount of time that I like to think about the history of the planet from when it formed until now in terms of a single minute. On this scale, the dinosaurs were around three seconds ago and humans evolved three one-hundredths of a second before the present. In the history of the Earth we’ve been around about [click fingers] that long! So what happened in the other 57 seconds? About half a second after the Earth formed, the moon formed.
Skip to 0 minutes and 35 seconds Then the Earth passed through a rough patch known as the “late heavy bombardment” and at about 7.5 seconds into this one minute history, life started. This life was single-celled and microscopic. Microbial biology was the only game in town for the next 32.5 seconds - more than half the history of the planet. It’s important to appreciate that the Earth where life developed was a very different place to what it is now. There was essentially no oxygen in the atmosphere, although there was still nitrogen, carbon dioxide and inert gases. Life critically requires energy to impose order and rearrange chemicals into useful molecules. Nascent life had to work out how to use anaerobic chemical reactions as rather poor energy sources.
Skip to 1 minute and 16 seconds By physically compartmentalising molecules, microbes were able to use chemical reactions to move protons. They developed membranes as a barrier to keep protons out of cells. Then by letting protons into cells through an ATP synthase, they were able to harness “proton motive force” to do work, like a turbine driven by water pressure generated by a dam. Amazingly, at 14 seconds into the history of the planet, and only half a billion years after they first appeared, microbes worked out how to harness the energy from sunlight by inventing photosynthesis! Photosynthesis also pumps protons to drive ATP synthase! The ready availability of limitless energy provided an opportunity for biology to make some technological advances - such as the splitting of water.
Skip to 2 minutes and 4 seconds Half way through this one minute history, biologically generated oxygen appeared in the Earth’s atmosphere. The “Great Oxygenation Event” - or “Great Oxygenation Catastrophe” from the point of view of the life that was thriving in its absence - provided opportunities for biology to evolve ways to harness more energetic chemistry, driving the development of multicellular life, which started to appear after about 40 seconds. The ferocious reactivity of molecular oxygen provided much higher energy yields for biological reactions, but also proved extremely toxic to many microbes. This huge selective pressure meant that microbes had to adapt or die.
Skip to 2 minutes and 42 seconds Many of them developed metabolic pathways to use oxygen and deal with dangerous reactive oxygen molecules, others - the strict anaerobes - found environmental niches on the planet away from oxygen, where they could continue to thrive.
A brief history of life
What does the history of the Earth look like if we condense it into a minute?
We start Week 1 by looking at Bugs, by which we mean microbes, single-celled organisms that are only visible down a microscope. Bugs come in three flavours:
- Archaea: probably the most ancient form of life, these microbes have evolved to be able to live in some of the most extreme environments on the planet including boiling water and concentrated acid.
- Bacteria: indistinguishable from archaea under the microscope, these bugs have very different biochemical pathways. There are more bacterial cells in and on your body than human ones!
- Single-celled Eukaryotes: these include organisms such as yeast and amoebae. Biochemically these bugs are almost exactly the same as animals, plants and humans, which are all multi-cellular eukaryotes.
Both bacteria and archaea are classified as prokaryotes. The terms prokaryote and eukaryote refer to how DNA is arranged in cells. Prokaryotic life has been around for BILLIONS of years, during which time the way in which they have grown has literally changed the face of the planet.
In this video, Prof. James Chong discusses some of the challenges that microbial life had to overcome as Bugs conquered the Earth. Here are some questions to consider while you’re watching the video. We’d be happy to hear from you in the comments once you’ve watched the video.
- Apart from energy, what other critical requirements are there for life?
- Most metabolic processes are energy generating. What do you think is the most energy-expensive process in a cell?
- Can you identify three niches where you would find anaerobic microbes now?
© University of York