Your search keyword '"Alveolata metabolism"' showing total 3 results

1. Evolutionary distinctiveness of fatty acid and polyketide synthesis in eukaryotes.

Author

Kohli GS, John U, Van Dolah FM, and Murray SA

Subjects

Alveolata metabolism, Biological Evolution, Chlorophyta metabolism, Dinoflagellida genetics, Dinoflagellida metabolism, Haptophyta, Phylogeny, Stramenopiles metabolism, Alveolata genetics, Chlorophyta genetics, Fatty Acids metabolism, Polyketides metabolism, Stramenopiles genetics

Abstract

Fatty acids, which are essential cell membrane constituents and fuel storage molecules, are thought to share a common evolutionary origin with polyketide toxins in eukaryotes. While fatty acids are primary metabolic products, polyketide toxins are secondary metabolites that are involved in ecologically relevant processes, such as chemical defence, and produce the adverse effects of harmful algal blooms. Selection pressures on such compounds may be different, resulting in differing evolutionary histories. Surprisingly, some studies of dinoflagellates have suggested that the same enzymes may catalyse these processes. Here we show the presence and evolutionary distinctiveness of genes encoding six key enzymes essential for fatty acid production in 13 eukaryotic lineages for which no previous sequence data were available (alveolates: dinoflagellates, Vitrella, Chromera; stramenopiles: bolidophytes, chrysophytes, pelagophytes, raphidophytes, dictyochophytes, pinguiophytes, xanthophytes; Rhizaria: chlorarachniophytes, haplosporida; euglenids) and 8 other lineages (apicomplexans, bacillariophytes, synurophytes, cryptophytes, haptophytes, chlorophyceans, prasinophytes, trebouxiophytes). The phylogeny of fatty acid synthase genes reflects the evolutionary history of the organism, indicating selection to maintain conserved functionality. In contrast, polyketide synthase gene families are highly expanded in dinoflagellates and haptophytes, suggesting relaxed constraints in their evolutionary history, while completely absent from some protist lineages. This demonstrates a vast potential for the production of bioactive polyketide compounds in some lineages of microbial eukaryotes, indicating that the evolution of these compounds may have played an important role in their ecological success.

Published

2016

2. The myriad roles of cyclic AMP in microbial pathogens: from signal to sword.

Author

McDonough KA and Rodriguez A

Subjects

Alveolata genetics, Bacteria genetics, Fungi genetics, Metabolic Networks and Pathways, Models, Biological, Virulence Factors biosynthesis, Alveolata metabolism, Bacteria metabolism, Cyclic AMP metabolism, Fungi metabolism, Gene Expression Regulation, Signal Transduction

Abstract

All organisms must sense and respond to their external environments, and this signal transduction often involves second messengers such as cyclic nucleotides. One such nucleotide is cyclic AMP, a universal second messenger that is used by diverse forms of life, including mammals, fungi, protozoa and bacteria. In this review, we discuss the many roles of cAMP in bacterial, fungal and protozoan pathogens and its contributions to microbial pathogenesis. These roles include the coordination of intracellular processes, such as virulence gene expression, with extracellular signals from the environment, and the manipulation of host immunity by increasing cAMP levels in host cells during infection.

Published

2011

3. Marine bacterial, archaeal and protistan association networks reveal ecological linkages.

Author

Steele JA, Countway PD, Xia L, Vigil PD, Beman JM, Kim DY, Chow CE, Sachdeva R, Jones AC, Schwalbach MS, Rose JM, Hewson I, Patel A, Sun F, Caron DA, and Fuhrman JA

Subjects

Alveolata classification, Alveolata genetics, Alveolata isolation & purification, Ammonia metabolism, Archaea classification, Archaea genetics, Archaea isolation & purification, Bacteria classification, Bacteria genetics, Bacteria isolation & purification, California, Marine Biology, Oceans and Seas, Plankton isolation & purification, Plankton metabolism, Polymerase Chain Reaction, Seawater parasitology, Sequence Analysis, DNA, Stramenopiles classification, Stramenopiles genetics, Stramenopiles isolation & purification, Alveolata metabolism, Archaea metabolism, Bacteria metabolism, Plankton classification, Seawater microbiology, Stramenopiles metabolism

Abstract

Microbes have central roles in ocean food webs and global biogeochemical processes, yet specific ecological relationships among these taxa are largely unknown. This is in part due to the dilute, microscopic nature of the planktonic microbial community, which prevents direct observation of their interactions. Here, we use a holistic (that is, microbial system-wide) approach to investigate time-dependent variations among taxa from all three domains of life in a marine microbial community. We investigated the community composition of bacteria, archaea and protists through cultivation-independent methods, along with total bacterial and viral abundance, and physico-chemical observations. Samples and observations were collected monthly over 3 years at a well-described ocean time-series site of southern California. To find associations among these organisms, we calculated time-dependent rank correlations (that is, local similarity correlations) among relative abundances of bacteria, archaea, protists, total abundance of bacteria and viruses and physico-chemical parameters. We used a network generated from these statistical correlations to visualize and identify time-dependent associations among ecologically important taxa, for example, the SAR11 cluster, stramenopiles, alveolates, cyanobacteria and ammonia-oxidizing archaea. Negative correlations, perhaps suggesting competition or predation, were also common. The analysis revealed a progression of microbial communities through time, and also a group of unknown eukaryotes that were highly correlated with dinoflagellates, indicating possible symbioses or parasitism. Possible 'keystone' species were evident. The network has statistical features similar to previously described ecological networks, and in network parlance has non-random, small world properties (that is, highly interconnected nodes). This approach provides new insights into the natural history of microbes.

Published

2011