Geobiology is founded upon a few core concepts that unite the study of Earth and life. While there are many aspects of studying past and present interactions between life and Earth that are unclear, several important ideas and concepts provide a basis of knowledge in geobiology that serve as a platform for posing researchable questions, including the evolution of life and planet and the co-evolution of the two, genetics - from both a historical and functional standpoint, the metabolic diversity of all life, the sedimentological preservation of past life, and the origin of life.
Co-evolution of Life and Earth A core concept in geobiology is that life changes over time through
evolution. The theory of evolution postulates that unique populations of organisms or
species arose from genetic modifications in the ancestral population which were passed down by
drift and
natural selection. Along with standard biological evolution, life and planets co-evolve. Since the best adaptations are those that suit the
ecological niche that the organism lives in, the physical and chemical characteristics of the environment drive the evolution of life by natural selection, but the opposite can also be true: with every advent of evolution, the environment changes. A classic example of co-evolution is the evolution of
oxygen-producing
photosynthetic cyanobacteria which oxygenated Earth's
Archean atmosphere. The ancestors of cyanobacteria began using water as an electron source to harness the energy of the sun and expelling oxygen before or during the early
Paleoproterozoic. During this time, around 2.4 to 2.1 billion years ago, geologic data suggests that atmospheric oxygen began to rise in what is termed the
Great Oxygenation Event (GOE). It is unclear for how long cyanobacteria had been doing oxygenic photosynthesis before the GOE. Some evidence suggests there were geochemical "buffers" or sinks suppressing the rise of oxygen such as
volcanism though cyanobacteria may have been around producing it before the GOE. Other evidence indicates that the rise of oxygenic photosynthesis was coincident with the GOE. (BIF),
Hammersley Formation, Western Australia The presence of oxygen on Earth from its first production by cyanobacteria to the GOE and through today has drastically impacted the course of evolution of life and planet. and the disappearance of oxidizable minerals like
pyrite from ancient stream beds. The presence of
banded-iron formations (BIFs) have been interpreted as a clue for the rise of oxygen since small amounts of oxygen could have reacted with reduced
ferrous iron (Fe(II)) in the oceans, resulting in the deposition of sediments containing
Fe(III) oxide in places like Western Australia. However, any oxidizing environment, including that provided by microbes such as the iron-oxidizing photoautotroph
Rhodopseudomonas palustris, can trigger iron oxide formation and thus BIF deposition. Other mechanisms include oxidation by
UV light. Indeed, BIFs occur across large swaths of Earth's history and may not correlate with only one event.. In Early earth, and even now, phosphate was generally considered a limiting nutrient for life. Pyrite , being positively charged, can concentrate anionic phosphate and phosphorylated organic molecules. The free energy yield from anaerobic biomineralization of pyrites by chemoautotrophs is enough for supporting life. Some scientists have also proposed that clay minerals facilitated the origin of life. Clay and clay minerals, such as kaolinite, montmorillonite, and beidellite have been widely distributed in geologic time and space. The interaction of active sites on clay mineral surfaces with simple organic molecules concentrated them, along with protecting and preserving these molecules. This phenomenon is not supposedly limited to just Earth, but also other planets, comets, meteorites and asteroids. The beginning of oxygenic photosynthesis has inevitably resulted in a wide range of reductants and oxidants, which expanded the metabolic diversity in microorganisms, particularly sulfur cycle. Anoxic conditions in the early ocean made sulfate limited due to pyrite formation and precipitation. After GOE, oxidative weathering of sulfide minerals such as pyrite increased rapidly. This resulted in increased sulfate transport in the ocean, which facilitated the evolution of other sulfur metabolisms like thiosulfate oxidation and reduction via sox pathway. Other trace element availability like Ni, Co, Cu, Fe, Cr etc have also impacted early life formation on Earth. Other changes correlated with the rise of oxygen include the appearance of rust-red ancient
paleosols, and global
glaciations and
Snowball Earth events, perhaps caused by the oxidation of
methane by oxygen, not to mention an overhaul of the types of organisms and metabolisms on Earth. Whereas organisms prior to the rise of oxygen were likely poisoned by oxygen gas as many
anaerobes are today, those that evolved ways to harness the electron-accepting and energy-giving power of oxygen were poised to thrive and colonize the aerobic environment. s in Shark Bay, Australia. Shark Bay is one of the few places in the world where stromatolites can be seen today, though they were likely common in ancient shallow seas before the rise of
metazoan predators.
The Earth has changed Earth has not remained the same since its planetary formation 4.5 billion years ago.
Continents have formed, broken up, and collided, offering new opportunities for and barriers to the dispersal of life. The redox state of the atmosphere and the oceans has changed, as indicated by isotopic data. Fluctuating quantities of inorganic compounds such as
carbon dioxide,
nitrogen,
methane, and
oxygen have been driven by life evolving new biological metabolisms to make these chemicals and have driven the evolution of new metabolisms to use those chemicals. Earth acquired a
magnetic field about 3.4 Ga that has undergone a series of
geomagnetic reversals on the order of millions of years. The surface temperature is in constant fluctuation, falling in glaciations and Snowball Earth events due to
ice–albedo feedback, rising and melting due to volcanic outgassing, and stabilizing due to
silicate weathering feedback. And the Earth is not the only one that changed - the
luminosity of the sun has increased over time. Because rocks record a history of relatively constant temperatures since Earth's beginnings, there must have been more
greenhouse gasses to keep the temperatures up in the Archean when the sun was younger and fainter. All these major differences in the environment of the Earth placed very different constraints on the evolution of life throughout our planet's history. Moreover, more subtle changes in the habitat of life are always occurring, shaping the organisms and traces that we observe today and in the rock record.
Genes encode geobiological function and history The
genetic code is key to observing the history of
evolution and understanding the capabilities of organisms.
Genes are the basic unit of
inheritance and function and, as such, they are the basic unit of evolution and the means behind
metabolism.
Phylogeny predicts evolutionary history of living things, based on
rRNA data and proposed by
Carl Woese, showing the separation of
bacteria,
archaea, and
eukaryotes and linking the three branches of living organisms to the
LUCA (the black trunk at the bottom of the tree).
Phylogeny takes genetic sequences from living organisms and compares them to each other to reveal evolutionary relationships, much like a family tree reveals how individuals are connected to their distant cousins. It allows us to decipher modern relationships and infer how evolution happened in the past. Phylogeny can give some sense of history when combined with a little bit more information. Each difference in the DNA indicates divergence between one species and another. From there, with an idea about other contemporaneous changes in life and environment, we can begin to speculate why certain evolutionary paths might have been selected for.
Genes encode metabolism Molecular biology allows scientists to understand a gene's function using
microbial culturing and
mutagenesis. Searching for similar genes in other organisms and in
metagenomic and
metatranscriptomic data allows us to understand what processes could be relevant and important in a given ecosystem, providing insight into the biogeochemical cycles in that environment. For example, an intriguing problem in geobiology is the role of organisms in the global cycling of
methane. Genetics has revealed that the methane monooxygenase gene (
pmo) is used for oxidizing methane and is present in all aerobic methane-oxidizers, or
methanotrophs. The presence of DNA sequences of the
pmo gene in the environment can be used as a proxy for methanotrophy. A more generalizable tool is the
16S ribosomal RNA gene, which is found in bacteria and archaea. This gene evolves very slowly over time and is not usually
horizontally transferred, and so it is often used to distinguish different taxonomic units of organisms in the environment. In this way, genes are clues to organismal metabolism and identity. Genetics enables us to ask 'who is there?' and 'what are they doing?' This approach is called
metagenomics. stromatolites from Warrawoona are hypothesized to have been formed by ancient communities of microbes.
Metabolic diversity influences the environment Microbial life on Earth evolved around 3.5 billion years ago. Given the fact that the earth is about 4.5 billion years old, they have occupied about 87% of Earth's History. Since their origin, microbes have established, maintained and improved all major biogeochemical cycles for billions of years. So it is not an overstatement to say microbes are the foundation of the biosphere. Life harnesses chemical reactions to generate energy, perform
biosynthesis, and eliminate waste. Different organisms use very different metabolic approaches to meet these basic needs. While animals such as ourselves are limited to
aerobic respiration, other organisms can "breathe"
sulfate (SO42-),
nitrate (NO3-),
ferric iron (Fe(III)), and
uranium (U(VI)), or live off energy from
fermentation. s of the
Johnnie Formation in the Death Valley area, California, USA. Ooids are near-spheroidal
calcium carbonate grains that accumulate around a central nucleus and can be sedimented to form oolite like this. Microbes can mediate the formation of ooids. While often delegated to the field of
astrobiology, attempts to understand how and when life arose are relevant to geobiology as well. The first major strides towards understanding the “how” came with the
Miller-Urey experiment, when amino acids formed out of a simulated “
primordial soup”. Another theory is that life originated in a system much like the
hydrothermal vents at
mid-oceanic spreading centers. In the
Fischer-Tropsch synthesis, a variety of
hydrocarbons form under vent-like conditions. Other ideas include the
“RNA World” hypothesis, which postulates that the first biologic molecule was
RNA, and the idea that life originated elsewhere in the
Solar System and was brought to Earth, perhaps via a
meteorite. == Methodology ==