Metallomics, elementomics, and analytical techniques

Li, Yu Feng; Chen, Chunying; Qu, Ying; Gao, Yuxi; Bai, Li; Yang, Zhao; Chai, Zhifang

doi:10.1351/pac200880122577

Cited by 46 publications

(25 citation statements)

References 337 publications

(162 reference statements)

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“…Clearly, not all chemical elements occur in an ionic form, as they can also form covalent compounds as in the case of iodine or selenium, for example. It includes all the chemical elements (Li et al 2008). Since metal ions and non-metals are metabolites, the discipline has also been referred to as elemental metabolomics (Zhang et al 2017).…”

Section: The Copper Metallomementioning

confidence: 99%

Metallomics: The Science of Biometals and Biometalloids

Maret

2018

Advances in Experimental Medicine and Biology

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Metallomics, a discipline integrating sciences that address the biometals and biometalloids, provides new opportunities for discoveries. As part of a systems biology approach, it draws attention to the importance of many chemical elements in biochemistry. Traditionally, biochemistry has treated life as organic chemistry, separating it from inorganic chemistry, considered a field reserved for investigating the inanimate world. However, inorganic chemistry is part of the chemistry of life, and metallomics contributes by showing the importance of a neglected fifth branch of building blocks in biochemistry. Metallomics adds chemical elements/metals to the four building blocks of biomolecules and the fields of their studies: carbohydrates (glycome), lipids (lipidome), proteins (proteome), and nucleotides (genome). The realization that non-essential elements are present in organisms in addition to essential elements represents a certain paradigm shift in our thinking, as it stipulates inquiries into the functional implications of virtually all the natural elements. This article discusses opportunities arising from metallomics for a better understanding of human biology and health. It looks at a biological periodic system of the elements as a sum of metallomes and focuses on the major roles of metals in about 30-40% of all proteins, the metalloproteomes. It emphasizes the importance of zinc and iron biology and discusses why it is important to investigate non-essential metal ions, what bioinformatics approaches can contribute to understanding metalloproteins, and why metallomics has a bright future in the many dimensions it covers.

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Section: The Copper Metallomementioning

confidence: 99%

Metallomics: The Science of Biometals and Biometalloids

Maret

2018

Advances in Experimental Medicine and Biology

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“…A less trivial example is the relation between metallomics or microelementomics (Li, 2008) and an old Mallory method of lead and copper determination (Mallory, 1939), because to the best of our knowledge the methods of cellular metallomic and elementomic mapping have not yet been developed. A more intriguing example is the correlation between connectomics (Lichtman, 2008; Kennedy, 2010) and the topography of neurophanes (Neresheimer, 1903) and similar elements of the Protozoa body (as a simple example of the convergence or parallelism or pseudo-homology between Protozoa and Metazoa organizations), based on the semblances or propinquities of the Mallory staining results of the nervous media (Schümperli, 1977) and a neuromotor apparatus of Protozoa, as well as the relations between histomics or tissomics (Ecker, 2005; Kriete, 2006) of the synaptic neuromotor connections and the complexes of Metazoa and the neuromotor apparatus conjunctions or the branches of neurophanes, contacting with the myonems or spasmonems (Febvre, 1981).…”

Section: From Kinetome and Argyrome Towards Kinetomics And Argyromicsmentioning

confidence: 99%

Is it possible to consider «kinetomics» and «argyromics» as novel trends of functional morphology and systems biology of parasitic and nonparasitic protozoa? a brief analytical review

Градов¹

2016

Journal of Biomedical Technologies

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Abstract. This paper considers argyrophilic (i.e. stained by the silver nitrate) fibrils visualized by the well-known Klein method and later called neuroformative system of Protozoa, or neuroformium. Klein described the excitation wave propagation and coordination of the cilia moving by this network, as well as the main role in localization of the peristomes and the ciliar apparatus on the topographic microanatomy map of Protozoa before and after the cell division. However, in early 1930-th the advanced staining techniques revealed two components in the above mentioned fibrill network with the similar morphobiochemical parameters (within the limits of the silver nitrate staining selectivity), one of which provides the mechanical stabilization of the Protozoa body (a number of Paramecium species were found to possess even a third selectivelystained fiber system). This resulted in the introduction of the term "argyrome" by Chatton in 1936 for the complex of the argentophilic fibrils and a term "cinetome" for the subpellicular infraciliature. It is therefore more appropriate to speak about "kinetomics" and "argyromics" rather than of a single "omics" for all the intracellular networks of Protozoa. We consider the principles of introduction of the novel "-omics" in modern science and from the above standpoint discuss whether it is possible to consider "kinetomics" and "argyromics" as the novel trends of functional morphology and systems biology of Protozoa.

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“…For quantitative determination of trace metals in biological systems, ICP-MS and atomic spectrometry techniques are the best choices. ICP-MS, featuring high sensitivity and wide linear dynamic range, allows robust, accurate and multielemental detection for most metallic and metalloid elements [38,61]. By coupling with a front-end chromatography separation system, an on-line analysis could be performed for identifying and quantifying metal binding proteins in solution.…”

Section: Application Of Liquid Chromatography (Lc)/gel Electrophoresimentioning

confidence: 99%

Metallomics in environmental and health related research: Current status and perspectives

Wang

et al. 2012

Chin. Sci. Bull.

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Metals and metalloids play distinct roles in human health, either beneficial or toxic, depending on their concentrations and species. There is an increasing interest in metals uptake, trafficking, function, and exertion in microorganisms to maintain and advance human health. Metallomics, an emerging research area, focuses on elucidation of metals/metalloids location, distribution, speciation, and behavior in living organisms. This paper briefly summarized the recent progress on the methodology development of metallomics including various techniques, i.e. multiple dimensional liquid chromatography-inductively coupled plasma mass spectrometry (LC-ICPMS), gel electrophoresis-laser ablation-inductively coupled plasma mass spectrometry (GE-LA-ICPMS), synchrotron X-ray fluorescent spectroscopy (XFS), and the applications of metallomics in environmental and health care.

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Metallomics, elementomics, and analytical techniques

Cited by 46 publications

References 337 publications

Metallomics: The Science of Biometals and Biometalloids

Metallomics: The Science of Biometals and Biometalloids

Is it possible to consider «kinetomics» and «argyromics» as novel trends of functional morphology and systems biology of parasitic and nonparasitic protozoa? a brief analytical review

Metallomics in environmental and health related research: Current status and perspectives

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