What is an autotroph?

The concept of autotrophy depends on the growth media for pure cultures supplying a single one carbon source for anabolism. Secondary carbon compounds added to the medium as chelators and/or vitamins confuse the meaning. This note suggests a clarification of definition suitable for contemporary biochemical studies of true autotrophs.

Ligand field theory and the origin of life as an emergent feature of the periodic table of elements.

The assumption that all biological catalysts are either proteins or ribozymes leads to an outstanding enigma of biogenesis-how to determine the synthetic pathways to the monomers for the efficient formation of catalytic macromolecules in the absence of any such macromolecules. The last 60 years have witnessed chemists developing an understanding of organocatalysis and ligand field theory, both of which give demonstrable low-molecular-weight catalysts. We assume that transition-metal-ligand complexes are likely to have occurred in the deep ocean trenches by the combination of naturally occurring oceanic metals and ligands synthesized from the emergent CO(2), H(2), NH(3), H(2)S, and H(3)PO(4).

Analysis of the intermediary metabolism of a reductive chemoautotroph.

All extant life forms depend, directly or indirectly, on the autotrophic fixation of the dominant elements of the biosphere: carbon, hydrogen, nitrogen, oxygen, phosphorus, and sulfur. We have earlier presented the canonical network of reactions that constitute the anabolism of a reductive chemoautotroph. Separating this network into subgraphs reveals several empirical generalizations: (1) acetate (acetyl-CoA), pyruvate, phosphoenol pyruvate, oxaloacetate, and 2-oxoglutarate serve as universal starting points for all pathways leading to the universal building blocks-20 amino acids and 4 ribonucleotide triphosphates; (2) all pathways are anabolic; (3) all reactions operate by complete utilization of outputs with no molecules left behind as waste, ensuring conservation of information; (4) the core metabolome of 120 compounds is acidic, consisting of compounds containing phosphoric or carboxylic acid or both; and (5) the core network is both brittle-vulnerable to a single break-and robust-having persisted for 4 billion years.

The canonical network of autotrophic intermediary metabolism: minimal metabolome of a reductive chemoautotroph.

Chemoautorophs that fix carbon by the reductive tricarboxylic acid cycle represent one of the dominant bacterial life forms that make a major contribution to biomass production. From the viewpoint of biogenesis, construction of a canonical chart of intermediary metabolism for this class of organisms may help us to understand early cellular evolution and point us to the last universal common ancestor. Data-mining the KEGG Pathways database enabled us to integrate required biosynthetic pathways and derive a chart that represents the complete anabolic network of a reductive chemoautotroph.

Ancient genes in contemporary persistent microbial pathogens.

Autotrophs, the earliest prokaryotes, use CO(2) as the sole or the key source in the reductive citric acid cycle for carbon fixation. This pathway, also known as the reductive tricarboxylic acid (rTCA) cycle, has as its center the Krebs cycle running in the reductive direction, using reduced cofactors for energy. During the infection process, persistent pathogenic bacteria like Mycobacterium tuberculosis, Helicobacter pylori, and Salmonella typhi experience diverse and hostile environments both intracellularly (in macrophages) and extracellularly.