This biographical article is written like a résumé .(March 2023) |
Mitchell Sogin grew up in Chicago and went to the University of Illinois on a swimming scholarship, intending to become a doctor. Instead he continued on at the university to complete a MS in Industrial Microbiology under Z. John Ordal in 1967 and a PhD in Microbiology and Molecular Biology under Carl R. Woese in 1972. An American microbiologist, he is now a distinguished senior scientist at the Marine Biological Laboratory in Woods Hole, Massachusetts. His research investigates the evolution and diversity of single-celled organisms. [1]
Sogin obtained a BS in Chemistry and Microbiology at the University of Illinois, Urbana in 1967. He went on to join the staff at National Jewish Health, Denver, Colorado where he was an NIH Postdoctoral Fellow in the lab of Norman R. Pace from 1972-1976 and then a senior staff member from 1976-1989. Sogin became a professor at the University of Colorado Health Sciences Center in 1980 and in 1989 joined the Marine Biological Laboratory at Woods Hole as a senior scientist. He founded the Josephine Bay Paul Center for Comparative Molecular Biology and Evolution at the Marine Biological Laboratory in 1997, and served as its director until 2013. Sogin has a professor appointment in the department of Molecular Biology, Cell Biology, and Biochemistry at Brown University. He is a fellow of the American Association for the Advancement of Science, the American Academy of Arts and Sciences and the American Academy of Microbiology and was a Miller Professor at the University of California at Berkeley. He received the Stoll Stunkard Award from the American Society of Parasitologists and the Roger Porter Award from the American Society for Microbiology. [2] Sogin serves as co-chair of the Scientific Steering Committee for the Deep Life Community of the Deep Carbon Observatory. [3]
Sogin’s molecular phylogeny from ribosomal RNA sequences provided a framework for reconstructing the evolution of microbial eukaryotes. [4] He documented early diverging eukaryotic lineages, giving the earliest evidence of a link between animals and fungi, to the exclusion of all other eukaryotes. His work demonstrated that the AIDS-related pathogen Pneumocystis shares a recent common ancestor with fungi instead of with the parasitic protozoa that cause malaria. [5] He also discovered the “rare biosphere” which represents most of Earth’s microbial diversity. [6] Sogin was the first to use PCR to amplify and sequence ribosomal RNA genes and to use next generation DNA sequencing to characterize complex microbial communities, which now dominates the field of molecular microbial ecology, including efforts underway within the Human Microbiome Project. He has contributed to analytical strategies to determine the taxonomic identity of marker gene surveys and with David Mark Welch of the Josephine Bay Paul Center has established the Visualization of Microbial Population Structures (VAMPS) website, which offers tools for comparing microbial community populations. [7] As part of the Census of Marine Life, Sogin formed and led the International Census of Marine Microbes. His group currently collaborates on studies of human microbiome dynamics with Eugene Chang of the University of Chicago. They study pouchitis, a model for ulcerative colitis. Sogin also serves on the editorial boards of the Journal of Eukaryotic Microbiology (formerly Journal of Protozoology), Molecular Phylogenetics and Evolution, Protist (formerly Archiv für Protistenkunde), Applied and Environmental Microbiology, and Environmental Microbiology. [2]
Carl Richard Woese was an American microbiologist and biophysicist. Woese is famous for defining the Archaea in 1977 through a pioneering phylogenetic taxonomy of 16S ribosomal RNA, a technique that has revolutionized microbiology. He also originated the RNA world hypothesis in 1967, although not by that name. Woese held the Stanley O. Ikenberry Chair and was professor of microbiology at the University of Illinois Urbana–Champaign.
A unicellular organism, also known as a single-celled organism, is an organism that consists of a single cell, unlike a multicellular organism that consists of multiple cells. Organisms fall into two general categories: prokaryotic organisms and eukaryotic organisms. Most prokaryotes are unicellular and are classified into bacteria and archaea. Many eukaryotes are multicellular, but some are unicellular such as protozoa, unicellular algae, and unicellular fungi. Unicellular organisms are thought to be the oldest form of life, with early protocells possibly emerging 3.8–4.0 billion years ago.
Microbial ecology is the ecology of microorganisms: their relationship with one another and with their environment. It concerns the three major domains of life—Eukaryota, Archaea, and Bacteria—as well as viruses.
Photosynthetic picoplankton or picophytoplankton is the fraction of the phytoplankton performing photosynthesis composed of cells between 0.2 and 2 µm in size (picoplankton). It is especially important in the central oligotrophic regions of the world oceans that have very low concentration of nutrients.
Archaea is a domain of single-celled organisms. These microorganisms lack cell nuclei and are therefore prokaryotes. Archaea were initially classified as bacteria, receiving the name archaebacteria, but this term has fallen out of use.
Microbiota are the range of microorganisms that may be commensal, mutualistic, or pathogenic found in and on all multicellular organisms, including plants. Microbiota include bacteria, archaea, protists, fungi, and viruses, and have been found to be crucial for immunologic, hormonal, and metabolic homeostasis of their host.
The eukaryotes constitute the domain of Eukaryota, organisms whose cells have a nucleus. All animals, plants, fungi, and many unicellular organisms are eukaryotes. They constitute a major group of life forms, alongside the two groups of prokaryotes, the Bacteria and the Archaea. Eukaryotes represent a small minority of the number of organisms, but due to their generally much larger size, their collective global biomass is much larger than that of prokaryotes.
Edward Francis DeLong, is a marine microbiologist and professor in the Department of Oceanography at the University of Hawaii, Manoa, and is considered a pioneer in the field of metagenomics. He is best known for his discovery of the bacterial use of the rhodopsin protein in converting sunlight to biochemical energy in marine microbial communities.
Marine microorganisms are defined by their habitat as microorganisms living in a marine environment, that is, in the saltwater of a sea or ocean or the brackish water of a coastal estuary. A microorganism is any microscopic living organism or virus, that is too small to see with the unaided human eye without magnification. Microorganisms are very diverse. They can be single-celled or multicellular and include bacteria, archaea, viruses and most protozoa, as well as some fungi, algae, and animals, such as rotifers and copepods. Many macroscopic animals and plants have microscopic juvenile stages. Some microbiologists also classify viruses as microorganisms, but others consider these as non-living.
The Earth Microbiome Project (EMP) is an initiative founded by Janet Jansson, Jack Gilbert and Rob Knight in 2010 to collect natural samples and to analyze the microbial community around the globe.
Alexandra (Alex) Z. Worden is a microbial ecologist and genome scientist known for her expertise in the ecology and evolution of ocean microbes and their influence on global biogeochemical cycles.
A microbiome is the community of microorganisms that can usually be found living together in any given habitat. It was defined more precisely in 1988 by Whipps et al. as "a characteristic microbial community occupying a reasonably well-defined habitat which has distinct physio-chemical properties. The term thus not only refers to the microorganisms involved but also encompasses their theatre of activity". In 2020, an international panel of experts published the outcome of their discussions on the definition of the microbiome. They proposed a definition of the microbiome based on a revival of the "compact, clear, and comprehensive description of the term" as originally provided by Whipps et al., but supplemented with two explanatory paragraphs. The first explanatory paragraph pronounces the dynamic character of the microbiome, and the second explanatory paragraph clearly separates the term microbiota from the term microbiome.
Mycoplankton are saprotrophic members of the plankton communities of marine and freshwater ecosystems. They are composed of filamentous free-living fungi and yeasts that are associated with planktonic particles or phytoplankton. Similar to bacterioplankton, these aquatic fungi play a significant role in heterotrophicmineralization and nutrient cycling. Mycoplankton can be up to 20 mm in diameter and over 50 mm in length.
A holobiont is an assemblage of a host and the many other species living in or around it, which together form a discrete ecological unit through symbiosis, though there is controversy over this discreteness. The components of a holobiont are individual species or bionts, while the combined genome of all bionts is the hologenome. The holobiont concept was initially introduced by the German theoretical biologist Adolf Meyer-Abich in 1943, and then apparently independently by Dr. Lynn Margulis in her 1991 book Symbiosis as a Source of Evolutionary Innovation. The concept has evolved since the original formulations. Holobionts include the host, virome, microbiome, and any other organisms which contribute in some way to the functioning of the whole. Well-studied holobionts include reef-building corals and humans.
Microbial DNA barcoding is the use of DNA metabarcoding to characterize a mixture of microorganisms. DNA metabarcoding is a method of DNA barcoding that uses universal genetic markers to identify DNA of a mixture of organisms.
All animals on Earth form associations with microorganisms, including protists, bacteria, archaea, fungi, and viruses. In the ocean, animal–microbial relationships were historically explored in single host–symbiont systems. However, new explorations into the diversity of marine microorganisms associating with diverse marine animal hosts is moving the field into studies that address interactions between the animal host and a more multi-member microbiome. The potential for microbiomes to influence the health, physiology, behavior, and ecology of marine animals could alter current understandings of how marine animals adapt to change, and especially the growing climate-related and anthropogenic-induced changes already impacting the ocean environment.
Abigail A. Salyers was a microbiologist who pioneered the field of human microbiome research. Her work on the bacterial phylum Bacteroidetes and its ecology led to a better understanding of antibiotic resistance and mobile genetic elements. At a time where the prevailing paradigm was focused on E. coli as a model organism, Salyers emphasized the importance of investigating the breadth of microbial diversity. She was one of the first to conceptualize the human body as a microbial ecosystem. Over the course of her 40 year career, she was presented with numerous awards for teaching and research and an honorary degree from ETH Zurich, and served as president of the American Society for Microbiology.
A. Murat Eren (Meren) is a computer scientist known for his work on microbial ecology and developing novel, open-source, computational tools for analysis of large data sets.
The holobiont concept is a renewed paradigm in biology that can help to describe and understand complex systems, like the host-microbe interactions that play crucial roles in marine ecosystems. However, there is still little understanding of the mechanisms that govern these relationships, the evolutionary processes that shape them and their ecological consequences. The holobiont concept posits that a host and its associated microbiota with which it interacts, form a holobiont, and have to be studied together as a coherent biological and functional unit to understand its biology, ecology, and evolution.
The two-domain system is a biological classification by which all organisms in the tree of life are classified into two big domains, Bacteria and Archaea. It emerged from development in the knowledge of archaea diversity and challenge over the widely accepted three-domain system that defines life into Bacteria, Archaea, and Eukarya. It was predicted by the eocyte hypothesis of James A. Lake in the 1980s, which was largely superseded by the three-domain system due to better compelling evidences at the time. Better understanding of archaea, especially in their roles in the origin of eukaryotes by symbiogenesis with bacteria, led to the revival of the eocyte hypothesis in the 2000s. The two-domain system became widely appreciated after the discovery of a large group (superphylum) of archaea called Asgard in 2017, evidences of which suggest to be the evolutionary root of eukaryotes – implying that eukaryotes are members of the domain Archaea.