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{{short description|Computational and mathematical modeling of complex biological systems}}
{{Short description|Computational and mathematical modeling of complex biological systems}}
{{Complex systems}}
{{Complex systems}}
[[File:Genomics GTL Pictorial Program.jpg|thumb|An illustration of the systems approach to biology]]
[[File:Genomics GTL Pictorial Program.jpg|thumb|An illustration of the systems approach to biology]]
{{Not to be confused with | Systematic biology}}

'''Systems biology''' is the [[computational modeling|computational]] and [[mathematical]] analysis and modeling of complex [[biological system]]s. It is a [[biology]]-based interdisciplinary field of study that focuses on complex interactions within biological systems, using a holistic approach ([[holism]] instead of the more traditional [[reductionist|reductionism]]) to biological research.<ref name="Tavassoly 487–500">{{Cite journal|last1=Tavassoly|first1=Iman|last2=Goldfarb|first2=Joseph|last3=Iyengar|first3=Ravi|date=2018-10-04|title=Systems biology primer: the basic methods and approaches|journal=Essays in Biochemistry|volume=62|issue=4|pages=487–500|doi=10.1042/EBC20180003|issn=0071-1365|pmid=30287586|s2cid=52922135}}</ref>
'''Systems biology''' is the [[computational modeling|computational]] and [[mathematical]] analysis and modeling of complex [[biological system]]s. It is a [[biology]]-based interdisciplinary field of study that focuses on complex interactions within biological systems, using a holistic approach ([[holism]] instead of the more traditional [[reductionist|reductionism]]) to biological research.<ref name="Tavassoly 487–500">{{Cite journal|last1=Tavassoly|first1=Iman|last2=Goldfarb|first2=Joseph|last3=Iyengar|first3=Ravi|date=2018-10-04|title=Systems biology primer: the basic methods and approaches|journal=Essays in Biochemistry|volume=62|issue=4|pages=487–500|doi=10.1042/EBC20180003|issn=0071-1365|pmid=30287586|s2cid=52922135}}</ref>


Particularly from the year 2000 onwards, the concept has been used widely in biology in a variety of contexts. The [[Human Genome Project]] is an example of applied [[systems thinking]] in biology which has led to new, collaborative ways of working on problems in the biological field of genetics.<ref>{{cite book|last1=Zewail|first1=Ahmed|title=Physical Biology: From Atoms to Medicine|date=2008|publisher=Imperial College Press|page=339}}</ref> One of the aims of systems biology is to model and discover [[emergent property|emergent properties]], properties of [[cell (biology)|cell]]s, [[tissue (biology)|tissue]]s and [[organism]]s functioning as a [[system]] whose theoretical description is only possible using techniques of systems biology.<ref name="Tavassoly 487–500"/><ref>{{Cite book|title=Perspectives on Organisms - Springer|last1=Longo|first1=Giuseppe|last2=Montévil|first2=Maël|doi=10.1007/978-3-642-35938-5|series=Lecture Notes in Morphogenesis|year=2014|isbn=978-3-642-35937-8|s2cid=27653540}}</ref> These typically involve [[metabolic networks]] or [[cell signaling]] networks.<ref name="Tavassoly 487–500"/><ref name="pmid21570668">{{cite book|author=Bu Z, Callaway DJ|title=Protein Structure and Diseases|volume=83|pages=163–221|year=2011|pmid=21570668|doi=10.1016/B978-0-12-381262-9.00005-7|series=Advances in Protein Chemistry and Structural Biology|isbn=978-0-123-81262-9|chapter=Proteins MOVE! Protein dynamics and long-range allostery in cell signaling}}</ref><ref>{{cite book |vauthors=Monga I, Randhawa V, Dhanda SK |chapter=Connecting the Dots: Using Machine Learning to Forge Gene Regulatory Networks from Large Biological Datasets. At the Intersection of GRNs: Where System Biology Meets Machine Learning |veditors=Singh S |title=Machine Learning and Systems Biology in Genomics and Health |isbn=978-981-16-5993-5 |pages=965–974 |date=2022 |doi=10.1007/978-981-16-5993-5_6|s2cid=246582031 }}</ref>
Particularly from the year 2000 onwards, the concept has been used widely in biology in a variety of contexts. The [[Human Genome Project]] is an example of applied [[systems thinking]] in biology which has led to new, collaborative ways of working on problems in the biological field of genetics.<ref>{{cite book|last1=Zewail|first1=Ahmed|title=Physical Biology: From Atoms to Medicine|date=2008|publisher=Imperial College Press|page=339}}</ref> One of the aims of systems biology is to model and discover [[emergent property|emergent properties]], properties of [[cell (biology)|cell]]s, [[tissue (biology)|tissue]]s and [[organism]]s functioning as a [[system]] whose theoretical description is only possible using techniques of systems biology.<ref name="Tavassoly 487–500"/><ref>{{Cite book|title=Perspectives on Organisms - Springer|last1=Longo|first1=Giuseppe|last2=Montévil|first2=Maël|doi=10.1007/978-3-642-35938-5|series=Lecture Notes in Morphogenesis|year=2014|isbn=978-3-642-35937-8|s2cid=27653540}}</ref> These typically involve [[metabolic networks]] or [[cell signaling]] networks.<ref name="Tavassoly 487–500"/><ref name="pmid21570668">{{cite book|author=Bu Z, Callaway DJ|title=Protein Structure and Diseases|volume=83|pages=163–221|year=2011|pmid=21570668|doi=10.1016/B978-0-12-381262-9.00005-7|series=Advances in Protein Chemistry and Structural Biology|isbn=978-0-123-81262-9|chapter=Proteins MOVE! Protein dynamics and long-range allostery in cell signaling}}</ref>


== Overview ==
== Overview ==
{{Essay-like|section|date=December 2022}}
Systems biology can be considered from a number of different aspects.
Systems biology can be considered from a number of different aspects.


As a field of study, particularly, the study of the interactions between the components of biological systems, and how these interactions give rise to the function and behavior of that system (for example, the [[enzymes]] and [[metabolites]] in a [[metabolic pathway]] or the heart beats).<ref name="snoep05" /><ref name="21stcentury" /><ref name="noble06" />
As a field of study, particularly, the study of the interactions between the components of biological systems, and how these interactions give rise to the function and behavior of that system (for example, the [[enzymes]] and [[metabolites]] in a [[metabolic pathway]] or the heart beats).<ref name="snoep05" /><ref name="21stcentury" /><ref name="noble06" />


As a [[paradigm]], systems biology is usually defined in antithesis to the so-called [[reductionist]] paradigm ([[biological organisation]]), although it is consistent with the [[scientific method]]. The distinction between the two paradigms is referred to in these quotations: "the [[Reductionism|reductionist]] approach has successfully identified most of the components and many of the interactions but, unfortunately, offers no convincing concepts or methods to understand how system properties emerge&nbsp;... the pluralism of causes and effects in biological networks is better addressed by observing, through quantitative measures, multiple components simultaneously and by rigorous data integration with mathematical models." (Sauer ''et al.'')<ref name="sauer07" /> "Systems biology&nbsp;... is about putting together rather than taking apart, integration rather than reduction. It requires that we develop ways of thinking about integration that are as rigorous as our reductionist programmes, but different.&nbsp;... It means changing our philosophy, in the full sense of the term." ([[Denis Noble]])<ref name="noble06" />
As a [[paradigm]], systems biology is usually defined in antithesis to the so-called [[reductionist]] paradigm ([[biological organisation]]), although it is consistent with the [[scientific method]]. The distinction between the two paradigms is referred to in these quotations: "the [[reductionism|reductionist]] approach has successfully identified most of the components and many of the interactions but, unfortunately, offers no convincing concepts or methods to understand how system properties emerge&nbsp;... the pluralism of causes and effects in biological networks is better addressed by observing, through quantitative measures, multiple components simultaneously and by rigorous data integration with mathematical models." (Sauer ''et al.'')<ref name="sauer07" /> "Systems biology&nbsp;... is about putting together rather than taking apart, integration rather than reduction. It requires that we develop ways of thinking about integration that are as rigorous as our reductionist programmes, but different.&nbsp;... It means changing our philosophy, in the full sense of the term." ([[Denis Noble]])<ref name="noble06" />


As a series of operational [[protocol (natural sciences)|protocol]]s used for performing research, namely a cycle composed of theory, [[Mathematical model|analytic]] or [[computational model]]ling to propose specific testable hypotheses about a biological system, experimental validation, and then using the newly acquired quantitative description of cells or cell processes to refine the computational model or theory.<ref name="kholodenko05" /> Since the objective is a model of the interactions in a system, the experimental techniques that most suit systems biology are those that are system-wide and attempt to be as complete as possible. Therefore, [[transcriptomics]], [[metabolomics]], [[proteomics]] and [[High-throughput screening|high-throughput techniques]] are used to collect quantitative data for the construction and validation of models.<ref name=Romualdi09 />
As a series of operational [[protocol (natural sciences)|protocol]]s used for performing research, namely a cycle composed of theory, [[Mathematical model|analytic]] or [[computational model]]ling to propose specific testable hypotheses about a biological system, experimental validation, and then using the newly acquired quantitative description of cells or cell processes to refine the computational model or theory.<ref name="kholodenko05" /> Since the objective is a model of the interactions in a system, the experimental techniques that most suit systems biology are those that are system-wide and attempt to be as complete as possible. Therefore, [[transcriptomics]], [[metabolomics]], [[proteomics]] and [[High-throughput screening|high-throughput techniques]] are used to collect quantitative data for the construction and validation of models.<ref name=Romualdi09 />
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As the application of [[dynamical systems theory]] to [[molecular biology]]. Indeed, the focus on the dynamics of the studied systems is the main conceptual difference between systems biology and [[bioinformatics]].<ref name=Voit01>{{cite book|last1=Voit|first1=Eberhard|title=A First Course in Systems Biology|date=2012|publisher=Garland Science|isbn=9780815344674}}</ref>
As the application of [[dynamical systems theory]] to [[molecular biology]]. Indeed, the focus on the dynamics of the studied systems is the main conceptual difference between systems biology and [[bioinformatics]].<ref name=Voit01>{{cite book|last1=Voit|first1=Eberhard|title=A First Course in Systems Biology|date=2012|publisher=Garland Science|isbn=9780815344674}}</ref>


As a [[Socio-scientific issues|socioscientific]] phenomenon defined by the strategy of pursuing integration of complex data about the interactions in biological systems from diverse experimental sources using interdisciplinary tools and personnel.<ref>{{Cite book |last1=Baitaluk|first1=M. |chapter=System Biology of Gene Regulation |doi=10.1007/978-1-59745-524-4_4 |title=Biomedical Informatics |journal=<!--Bypass Citation bot --> |series=Methods in Molecular Biology |volume=569 |pages=55–87 |year=2009 |isbn=978-1-934115-63-3 |pmid=19623486 }}</ref>
As a socioscientific phenomenon defined by the strategy of pursuing integration of complex data about the interactions in biological systems from diverse experimental sources using interdisciplinary tools and personnel.<ref>{{Cite book |last1=Baitaluk|first1=M. |chapter=System Biology of Gene Regulation |doi=10.1007/978-1-59745-524-4_4 |title=Biomedical Informatics |journal=<!--Bypass Citation bot --> |series=Methods in Molecular Biology |volume=569 |pages=55–87 |year=2009 |isbn=978-1-934115-63-3 |pmid=19623486 }}</ref>


== History ==
== History ==
Systems biology was begun as a new field of science around 2000, when the Institute for Systems Biology was established in Seattle in an effort to lure "computational" type people who it was felt were not attracted to the academic settings of the university. The institute did not have a clear definition of what the field actually was: roughly bringing together people from diverse fields to use computers to holistically study biology in new ways.<ref name="careers" /> A Department of Systems Biology at Harvard Medical School was launched in 2003.<ref>{{cite web|title=HMS launches new department to study systems biology|url=https://news.harvard.edu/gazette/story/2003/09/hms-launches-new-department-to-study-systems-biology/|publisher=Harvard Gazette|date=September 23, 2003}}</ref> In 2006 it was predicted that the buzz generated by the "very fashionable" new concept would cause all the major universities to need a systems biology department, thus that there would be careers available for graduates with a modicum of ability in computer programming and biology.<ref name="careers" /> In 2006 the [[National Science Foundation]] put forward a challenge to build a mathematical model of the whole cell.{{Citation needed|date=October 2019}} In 2012 the first whole-cell model of ''[[Mycoplasma genitalium]]'' was achieved by the Karr Laboratory at the Mount Sinai School of Medicine in New York. The whole-cell model is able to predict viability of ''M. genitalium'' cells in response to genetic mutations.<ref>{{cite journal|last1=Karr|first1=Jonathan R.|last2=Sanghvi|first2=Jayodita C.|last3=Macklin|first3=Derek N.|last4=Gutschow|first4=Miriam V.|last5=Jacobs|first5=Jared M.|last6=Bolival|first6=Benjamin|last7=Assad-Garcia|first7=Nacyra|last8=Glass|first8=John I.|last9=Covert|first9=Markus W.|title=A Whole-Cell Computational Model Predicts Phenotype from Genotype|journal=Cell|date=July 2012|volume=150|issue=2|pages=389–401|doi=10.1016/j.cell.2012.05.044|pmid=22817898|pmc=3413483}}</ref>
Although the concept of a systems view of cellular function has been well understood since at least the 1930s,<ref>{{cite web |last1=Wright |first1=Sewall |title=Physiological and Evolutionary Theories of Dominance |url=https://www.jstor.org/stable/2457086 |website=The American Naturalist |pages=24–53 |date=1934}}</ref> technological limitations made it difficult to make systems wide measurements. The advent of microarray technology in the 1990s opened up an entire new visa for studying cells at the systems level. In 2000, the Institute for Systems Biology was established in Seattle in an effort to lure "computational" type people who it was felt were not attracted to the academic settings of the university. The institute did not have a clear definition of what the field actually was: roughly bringing together people from diverse fields to use computers to holistically study biology in new ways.<ref name="careers" /> A Department of Systems Biology at Harvard Medical School was launched in 2003.<ref>{{cite web|title=HMS launches new department to study systems biology|url=https://news.harvard.edu/gazette/story/2003/09/hms-launches-new-department-to-study-systems-biology/|publisher=Harvard Gazette|date=September 23, 2003}}</ref> In 2006 it was predicted that the buzz generated by the "very fashionable" new concept would cause all the major universities to need a systems biology department, thus that there would be careers available for graduates with a modicum of ability in computer programming and biology.<ref name="careers" /> In 2006 the [[National Science Foundation]] put forward a challenge to build a mathematical model of the whole cell.{{Citation needed|date=October 2019}} In 2012 the first whole-cell model of ''[[Mycoplasma genitalium]]'' was achieved by the Covert Laboratory at Stanford University. The whole-cell model is able to predict viability of ''M. genitalium'' cells in response to genetic mutations.<ref>{{cite journal|last1=Karr|first1=Jonathan R.|last2=Sanghvi|first2=Jayodita C.|last3=Macklin|first3=Derek N.|last4=Gutschow|first4=Miriam V.|last5=Jacobs|first5=Jared M.|last6=Bolival|first6=Benjamin|last7=Assad-Garcia|first7=Nacyra|last8=Glass|first8=John I.|last9=Covert|first9=Markus W.|title=A Whole-Cell Computational Model Predicts Phenotype from Genotype|journal=Cell|date=July 2012|volume=150|issue=2|pages=389–401|doi=10.1016/j.cell.2012.05.044|pmid=22817898|pmc=3413483}}</ref>


An earlier precursor of systems biology, as a distinct discipline, may have been by systems theorist [[Mihajlo Mesarovic]] in 1966 with an international symposium at the [[Case Western Reserve University|Case Institute of Technology]] in [[Cleveland]], Ohio, titled ''Systems Theory and Biology''. Mesarovic predicted that perhaps in the future there would be such as thing as "systems biology".<ref name="mesarovic68" /><ref name="science68" /> Other early precursors that focused on the view that biology should be analyzed as a system, rather than a simple collection of parts, were [[Metabolic Control Analysis]], developed by [[Henrik Kacser]] and Jim Burns<ref>{{cite journal
An earlier precursor of systems biology, as a distinct discipline, may have been by systems theorist [[Mihajlo Mesarovic]] in 1966 with an international symposium at the [[Case Western Reserve University|Case Institute of Technology]] in [[Cleveland]], Ohio, titled ''Systems Theory and Biology''. Mesarovic predicted that perhaps in the future there would be such a thing as "systems biology".<ref name="mesarovic68" /><ref name="science68" /> Other early precursors that focused on the view that biology should be analyzed as a system, rather than a simple collection of parts, were [[Metabolic Control Analysis]], developed by [[Henrik Kacser]] and Jim Burns<ref>{{cite journal
| last1 = Kacser
| last1 = Kacser
| first1 = H
| first1 = H
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| doi = 10.1111/j.1432-1033.1974.tb03318.x
| doi = 10.1111/j.1432-1033.1974.tb03318.x
| pmid = 4830198
| pmid = 4830198
| doi-access = free
}}</ref> and [[Biochemical Systems Theory]] developed by [[Michael Savageau]]<ref>{{Cite journal|url= https://www.sciencedirect.com/science/article/pii/S0022519369800263 |title=Journal of Theoretical Biology|date=December 1969 |volume=25 |issue=3 |pages=365–369 |doi=10.1016/S0022-5193(69)80026-3 |last1=Savageau |first1=Michael A. |pmid=5387046 }}</ref><ref>{{Cite journal|url= https://www.sciencedirect.com/science/article/pii/S0022519369800275 |title= Journal of Theoretical Biology|date= December 1969|volume= 25|issue= 3|pages= 370–379|doi= 10.1016/S0022-5193(69)80027-5|last1= Savageau|first1= Michael A.|pmid= 5387047}}</ref><ref>{{Cite journal|url= https://www.sciencedirect.com/science/article/pii/S0022519370800133 |title= Journal of Theoretical Biology |date= February 1970 |volume= 26 |issue= 2 |pages= 215–226 |doi= 10.1016/S0022-5193(70)80013-3 |last1= Savageau |first1= Michael A. |pmid= 5434343 }}</ref>
}}</ref> and [[Biochemical Systems Theory]] developed by [[Michael Savageau]]<ref>{{Cite journal|url= https://www.sciencedirect.com/science/article/pii/S0022519369800263 |title=Journal of Theoretical Biology|date=December 1969 |volume=25 |issue=3 |pages=365–369 |doi=10.1016/S0022-5193(69)80026-3 |last1=Savageau |first1=Michael A. |pmid=5387046 }}</ref><ref>{{Cite journal|url= https://www.sciencedirect.com/science/article/pii/S0022519369800275 |title= Journal of Theoretical Biology|date= December 1969|volume= 25|issue= 3|pages= 370–379|doi= 10.1016/S0022-5193(69)80027-5|last1= Savageau|first1= Michael A.|pmid= 5387047}}</ref><ref>{{Cite journal|url= https://www.sciencedirect.com/science/article/pii/S0022519370800133 |title= Journal of Theoretical Biology |date= February 1970 |volume= 26 |issue= 2 |pages= 215–226 |doi= 10.1016/S0022-5193(70)80013-3 |last1= Savageau |first1= Michael A. |pmid= 5434343 }}</ref>


According to [[Robert Rosen (theoretical biologist)|Robert Rosen]] in the 1960s, holistic biology had become passé by the early 20th century, as more empirical science dominated by molecular chemistry had become popular.<ref name="science68" /> Echoing him forty years later in 2006 Kling writes that the success of [[molecular biology]] throughout the 20th century had suppressed holistic computational methods.<ref name="careers" /> By 2011 the [[National Institute of Health|National Institutes of Health]] had made grant money available to support over ten systems biology centers in the United States,<ref>{{cite web|title=Systems Biology - National Institute of General Medical Sciences|url=http://www.nigms.nih.gov/Research/FeaturedPrograms/SysBio/|access-date=12 December 2012|archive-url=https://web.archive.org/web/20131019100123/http://www.nigms.nih.gov/Research/FeaturedPrograms/SysBio/|archive-date=19 October 2013}}</ref> but by 2012 Hunter writes that systems biology had not lived up to the hype, having promised more than it achieved, which had caused it to become a somewhat minor field with few practical applications. Nonetheless, proponents hoped that it might once prove more useful in the future.<ref name="hunter12" />
According to [[Robert Rosen (theoretical biologist)|Robert Rosen]] in the 1960s, holistic biology had become passé by the early 20th century, as more empirical science dominated by molecular chemistry had become popular.<ref name="science68" /> Echoing him forty years later in 2006 Kling writes that the success of [[molecular biology]] throughout the 20th century had suppressed holistic computational methods.<ref name="careers" /> By 2011 the [[National Institute of Health|National Institutes of Health]] had made grant money available to support over ten systems biology centers in the United States,<ref>{{cite web|title=Systems Biology - National Institute of General Medical Sciences|url=http://www.nigms.nih.gov/Research/FeaturedPrograms/SysBio/|access-date=12 December 2012|archive-url=https://web.archive.org/web/20131019100123/http://www.nigms.nih.gov/Research/FeaturedPrograms/SysBio/|archive-date=19 October 2013}}</ref> but by 2012 Hunter writes that systems biology still has someway to go to achieve its full potential. Nonetheless, proponents hoped that it might once prove more useful in the future.<ref name="hunter12" />


<!-- This is a misleading history, who says that any of these people were doing systems biology? All the sources are their own papers, before the concept existed as a field. I could make up a new field and call it "gooblygooks" and say Einstein was the founder, citing it to one of his famous works where he never mentions gooblygooks...
<!-- This is a misleading history, who says that any of these people were doing systems biology? All the sources are their own papers, before the concept existed as a field. I could make up a new field and call it "gooblygooks" and say Einstein was the founder, citing it to one of his famous works where he never mentions gooblygooks...
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Items that may be a computer database include: [[phenomics]], organismal variation in [[phenotype]] as it changes during its life span; [[genomics]], organismal [[deoxyribonucleic acid]] (DNA) sequence, including intra-organismal cell specific variation. (i.e., [[telomere]] length variation); [[epigenomics]]/[[epigenetics]], organismal and corresponding cell specific transcriptomic regulating factors not empirically coded in the genomic sequence. (i.e., [[DNA methylation]], [[Histone acetylation and deacetylation]], etc.); [[transcriptomics]], organismal, tissue or whole cell [[gene expression]] measurements by [[DNA microarray]]s or [[serial analysis of gene expression]]; [[interferomics]], organismal, tissue, or cell-level transcript correcting factors (i.e., [[RNA interference]]), [[proteomics]], organismal, tissue, or cell level measurements of proteins and peptides via [[two-dimensional gel electrophoresis]], [[mass spectrometry]] or multi-dimensional protein identification techniques (advanced [[High-performance liquid chromatography|HPLC]] systems coupled with [[mass spectrometry]]). Sub disciplines include [[phosphoproteomics]], [[glycoproteomics]] and other methods to detect chemically modified proteins; [[glycomics]], organismal, tissue, or cell-level measurements of [[carbohydrate]]s; [[lipidomics]], organismal, tissue, or cell level measurements of [[lipids]].{{citation needed|date=December 2020}}
Items that may be a computer database include: [[phenomics]], organismal variation in [[phenotype]] as it changes during its life span; [[genomics]], organismal [[deoxyribonucleic acid]] (DNA) sequence, including intra-organismal cell specific variation. (i.e., [[telomere]] length variation); [[epigenomics]]/[[epigenetics]], organismal and corresponding cell specific transcriptomic regulating factors not empirically coded in the genomic sequence. (i.e., [[DNA methylation]], [[Histone acetylation and deacetylation]], etc.); [[transcriptomics]], organismal, tissue or whole cell [[gene expression]] measurements by [[DNA microarray]]s or [[serial analysis of gene expression]]; [[interferomics]], organismal, tissue, or cell-level transcript correcting factors (i.e., [[RNA interference]]), [[proteomics]], organismal, tissue, or cell level measurements of proteins and peptides via [[two-dimensional gel electrophoresis]], [[mass spectrometry]] or multi-dimensional protein identification techniques (advanced [[High-performance liquid chromatography|HPLC]] systems coupled with [[mass spectrometry]]). Sub disciplines include [[phosphoproteomics]], [[glycoproteomics]] and other methods to detect chemically modified proteins; [[glycomics]], organismal, tissue, or cell-level measurements of [[carbohydrate]]s; [[lipidomics]], organismal, tissue, or cell level measurements of [[lipids]].{{citation needed|date=December 2020}}


The molecular interactions within the cell are also studied, this is called [[interactomics]].<ref>{{Cite journal|last1=Cusick|first1=Michael E.|last2=Klitgord|first2=Niels|last3=Vidal|first3=Marc|last4=Hill|first4=David E.|date=2005-10-15|title=Interactome: gateway into systems biology|journal=Human Molecular Genetics|language=en|volume=14|issue=suppl_2|pages=R171–R181|doi=10.1093/hmg/ddi335|pmid=16162640|issn=0964-6906|doi-access=free}}</ref> A discipline in this field of study is [[protein-protein interaction]]s, although interactomics includes the interactions of other molecules.{{citation needed|date=December 2020}} [[Neuroelectrodynamics]], where the computer's or a brain's computing function as a dynamic system is studied along with its (bio)physical mechanisms;<ref>{{Cite journal|last=Aur|first=Dorian|date=2012|title=From Neuroelectrodynamics to Thinking Machines|journal=Cognitive Computation|language=en|volume=4|issue=1|pages=4–12|doi=10.1007/s12559-011-9106-3|s2cid=12355069|issn=1866-9956}}</ref> and [[fluxomics]], measurements of the rates of metabolic reactions in a biological system (cell, tissue, or organism).<ref name=":1" />
The molecular interactions within the cell are also studied, this is called [[interactomics]].<ref>{{Cite journal|last1=Cusick|first1=Michael E.|last2=Klitgord|first2=Niels|last3=Vidal|first3=Marc|last4=Hill|first4=David E.|date=2005-10-15|title=Interactome: gateway into systems biology|journal=Human Molecular Genetics|language=en|volume=14|issue=suppl_2|pages=R171–R181|doi=10.1093/hmg/ddi335|pmid=16162640|issn=0964-6906|doi-access=free}}</ref> A discipline in this field of study is [[protein–protein interaction]]s, although interactomics includes the interactions of other molecules.{{citation needed|date=December 2020}} [[Neuroelectrodynamics]], where the computer's or a brain's computing function as a dynamic system is studied along with its (bio)physical mechanisms;<ref>{{Cite journal|last=Aur|first=Dorian|date=2012|title=From Neuroelectrodynamics to Thinking Machines|journal=Cognitive Computation|language=en|volume=4|issue=1|pages=4–12|doi=10.1007/s12559-011-9106-3|s2cid=12355069|issn=1866-9956}}</ref> and [[fluxomics]], measurements of the rates of metabolic reactions in a biological system (cell, tissue, or organism).<ref name=":1" />


In approaching a systems biology problem there are two main approaches. These are the top down and bottom up approach. The top down approach takes as much of the system into account as possible and relies largely on experimental results. The [[RNA-Seq]] technique is an example of an experimental top down approach. Conversely, the bottom up approach is used to create detailed models while also incorporating experimental data. An example of the bottom up approach is the use of circuit models to describe a simple gene network.<ref>{{Cite journal|title=Application of Top-Down and Bottom-up Systems Approaches in Ruminant Physiology and Metabolism|last=Loor|first=Khuram Shahzad and Juan J.|date=2012-07-31|journal=Current Genomics|volume=13|issue=5|pages=379–394|language=en|doi=10.2174/138920212801619269|pmc=3401895|pmid=23372424}}</ref>
In approaching a systems biology problem there are two main approaches. These are the top down and bottom up approach. The top down approach takes as much of the system into account as possible and relies largely on experimental results. The [[RNA-Seq]] technique is an example of an experimental top down approach. Conversely, the bottom up approach is used to create detailed models while also incorporating experimental data. An example of the bottom up approach is the use of circuit models to describe a simple gene network.<ref>{{Cite journal|title=Application of Top-Down and Bottom-up Systems Approaches in Ruminant Physiology and Metabolism|last=Loor|first=Khuram Shahzad and Juan J.|date=2012-07-31|journal=Current Genomics|volume=13|issue=5|pages=379–394|language=en|doi=10.2174/138920212801619269|pmc=3401895|pmid=23372424}}</ref>
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|year=2010|journal=Nature Reviews Cancer|volume=10|issue=3|pages=221–230|pmid=20179714|doi=10.1038/nrc2808|title=Dissecting cancer through mathematics: from the cell to the animal model |s2cid=24616792 }}</ref>
|year=2010|journal=Nature Reviews Cancer|volume=10|issue=3|pages=221–230|pmid=20179714|doi=10.1038/nrc2808|title=Dissecting cancer through mathematics: from the cell to the animal model |s2cid=24616792 }}</ref>


The systems biology approach often involves the development of [[Mechanism (biology)|mechanistic]] models, such as the reconstruction of [[dynamic system]]s from the quantitative properties of their elementary building blocks.<ref name="dibernardo03" /><ref name="dibernardo05" /><ref name="dynamicmodel" /><ref>{{cite journal|last1=Korkut|first1=A|last2=Wang|first2=W|last3=Demir|first3=E|last4=Aksoy|first4=BA|last5=Jing|first5=X|last6=Molinelli|first6=EJ|last7=Babur|first7=Ö|last8=Bemis|first8=DL|last9=Onur Sumer|first9=S|last10=Solit|first10=DB|last11=Pratilas|first11=CA|last12=Sander|first12=C|title=Perturbation biology nominates upstream-downstream drug combinations in RAF inhibitor resistant melanoma cells.|journal=eLife|date=18 August 2015|volume=4|pmid=26284497|doi=10.7554/eLife.04640|pmc=4539601}}</ref> For instance, a cellular network can be modelled mathematically using methods coming from [[chemical kinetics]]<ref name=":0">{{Cite journal|last1=Gupta|first1=Ankur|last2=Rawlings|first2=James B.|date=April 2014|title=Comparison of Parameter Estimation Methods in Stochastic Chemical Kinetic Models: Examples in Systems Biology|journal=AIChE Journal|volume=60|issue=4|pages=1253–1268|doi=10.1002/aic.14409|issn=0001-1541|pmc=4946376|pmid=27429455}}</ref> and [[control theory]]. Due to the large number of parameters, variables and constraints in cellular networks, numerical and computational techniques are often used (e.g., [[flux balance analysis]]).<ref name=dynamicmodel>{{cite book|last1=Tavassoly|first1=Iman|title=Dynamics of Cell Fate Decision Mediated by the Interplay of Autophagy and Apoptosis in Cancer Cells|date=2015|publisher=Springer International Publishing|isbn=978-3-319-14961-5|doi=10.1007/978-3-319-14962-2|series=Springer Theses|s2cid=89307028}}</ref><ref name=":0" />
The systems biology approach often involves the development of [[Mechanism (biology)|mechanistic]] models, such as the reconstruction of [[dynamic system]]s from the quantitative properties of their elementary building blocks.<ref name="dibernardo03" /><ref name="dibernardo05" /><ref name="dynamicmodel" /><ref>{{cite journal|last1=Korkut|first1=A|last2=Wang|first2=W|last3=Demir|first3=E|last4=Aksoy|first4=BA|last5=Jing|first5=X|last6=Molinelli|first6=EJ|last7=Babur|first7=Ö|last8=Bemis|first8=DL|last9=Onur Sumer|first9=S|last10=Solit|first10=DB|last11=Pratilas|first11=CA|last12=Sander|first12=C|title=Perturbation biology nominates upstream-downstream drug combinations in RAF inhibitor resistant melanoma cells.|journal=eLife|date=18 August 2015|volume=4|pmid=26284497|doi=10.7554/eLife.04640|pmc=4539601|doi-access=free}}</ref> For instance, a cellular network can be modelled mathematically using methods coming from [[chemical kinetics]]<ref name=":0">{{Cite journal|last1=Gupta|first1=Ankur|last2=Rawlings|first2=James B.|date=April 2014|title=Comparison of Parameter Estimation Methods in Stochastic Chemical Kinetic Models: Examples in Systems Biology|journal=AIChE Journal|volume=60|issue=4|pages=1253–1268|doi=10.1002/aic.14409|issn=0001-1541|pmc=4946376|pmid=27429455}}</ref> and [[control theory]]. Due to the large number of parameters, variables and constraints in cellular networks, numerical and computational techniques are often used (e.g., [[flux balance analysis]]).<ref name=dynamicmodel>{{cite book|last1=Tavassoly|first1=Iman|title=Dynamics of Cell Fate Decision Mediated by the Interplay of Autophagy and Apoptosis in Cancer Cells|date=2015|publisher=Springer International Publishing|isbn=978-3-319-14961-5|doi=10.1007/978-3-319-14962-2|series=Springer Theses|s2cid=89307028}}</ref><ref name=":0" />


== Bioinformatics and data analysis ==
== Bioinformatics and data analysis ==
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== Creating biological models ==
== Creating biological models ==
[[File:Toy_Biological_Model.jpg|thumb|326x326px|A simple three protein negative feedback loop modeled with mass action kinetic differential equations. Each protein interaction is described by a Michaelis–Menten reaction.<ref name=":03">{{Cite journal|last1=Transtrum|first1=Mark K.|last2=Qiu|first2=Peng|date=2016-05-17|title=Bridging Mechanistic and Phenomenological Models of Complex Biological Systems|journal=PLOS Computational Biology|volume=12|issue=5|pages=e1004915|doi=10.1371/journal.pcbi.1004915|pmid=27187545|pmc=4871498|arxiv=1509.06278|bibcode=2016PLSCB..12E4915T|issn=1553-7358}}</ref>]]
[[File:Toy_Biological_Model.jpg|thumb|326x326px|A simple three protein negative feedback loop modeled with mass action kinetic differential equations. Each protein interaction is described by a Michaelis–Menten reaction.<ref name=":03">{{Cite journal|last1=Transtrum|first1=Mark K.|last2=Qiu|first2=Peng|date=2016-05-17|title=Bridging Mechanistic and Phenomenological Models of Complex Biological Systems|journal=PLOS Computational Biology|volume=12|issue=5|pages=e1004915|doi=10.1371/journal.pcbi.1004915|pmid=27187545|pmc=4871498|arxiv=1509.06278|bibcode=2016PLSCB..12E4915T|issn=1553-7358 |doi-access=free }}</ref>]]
Researchers begin by choosing a biological pathway and diagramming all of the protein interactions. After determining all of the interactions of the proteins, [[mass action kinetics]] is utilized to describe the speed of the reactions in the system. Mass action kinetics will provide differential equations to model the biological system as a mathematical model in which experiments can determine the parameter values to use in the [[differential equation]]s.<ref>{{Cite journal|last1=Chellaboina|first1=V.|last2=Bhat|first2=S. P.|last3=Haddad|first3=W. M.|last4=Bernstein|first4=D. S.|date=August 2009|title=Modeling and analysis of mass-action kinetics|journal=IEEE Control Systems Magazine|volume=29|issue=4|pages=60–78|doi=10.1109/MCS.2009.932926|s2cid=12122032|issn=1941-000X}}</ref> These parameter values will be the reaction rates of each proteins interaction in the system. This model determines the behavior of certain proteins in biological systems and bring new insight to the specific activities of individual proteins. Sometimes it is not possible to gather all reaction rates of a system. Unknown reaction rates are determined by simulating the model of known parameters and target behavior which provides possible parameter values.<ref>{{Cite journal|last1=Brown|first1=Kevin S.|last2=Sethna|first2=James P.|date=2003-08-12|title=Statistical mechanical approaches to models with many poorly known parameters|journal=Physical Review E|volume=68|issue=2|pages=021904|doi=10.1103/physreve.68.021904|pmid=14525003|bibcode=2003PhRvE..68b1904B|issn=1063-651X}}</ref><ref name=":03" />
Researchers begin by choosing a biological pathway and diagramming all of the protein, gene, and/or metabolic pathways. After determining all of the interactions, [[mass action kinetics]] or [[Enzyme kinetics|enzyme kinetic rate laws]] are used to describe the speed of the reactions in the system. Using mass-conservation, the [[Biochemical systems equation|differential equations]] for the biological system can be constructed. Experiments or parameter fitting can be done to determine the parameter values to use in the [[differential equation]]s.<ref>{{Cite journal|last1=Chellaboina|first1=V.|last2=Bhat|first2=S. P.|last3=Haddad|first3=W. M.|last4=Bernstein|first4=D. S.|date=August 2009|title=Modeling and analysis of mass-action kinetics|journal=IEEE Control Systems Magazine|volume=29|issue=4|pages=60–78|doi=10.1109/MCS.2009.932926|s2cid=12122032|issn=1941-000X}}</ref> These parameter values will be the various kinetic constants required to fully describe the model. This model determines the behavior of species in biological systems and bring new insight to the specific activities of system. Sometimes it is not possible to gather all reaction rates of a system. Unknown reaction rates are determined by simulating the model of known parameters and target behavior which provides possible parameter values.<ref>{{Cite journal|last1=Brown|first1=Kevin S.|last2=Sethna|first2=James P.|date=2003-08-12|title=Statistical mechanical approaches to models with many poorly known parameters|journal=Physical Review E|volume=68|issue=2|pages=021904|doi=10.1103/physreve.68.021904|pmid=14525003|bibcode=2003PhRvE..68b1904B|issn=1063-651X}}</ref><ref name=":03" />


The use of constraint-based reconstruction and analysis (COBRA) methods has become popular among systems biologists to simulate and predict the metabolic phenotypes, using genome-scale models. One of the methods is the flux balance analysis (FBA) approach, by which one can study the biochemical networks and analyze the flow of metabolites through a particular metabolic network, by maximizing the object of interest.<ref>{{Cite journal|last1=Orth|first1=Jeffrey D|last2=Thiele|first2=Ines|last3=Palsson|first3=Bernhard Ø|date=March 2010|title=What is flux balance analysis?|journal=Nature Biotechnology|language=en|volume=28|issue=3|pages=245–248|doi=10.1038/nbt.1614|issn=1087-0156|pmc=3108565|pmid=20212490}}</ref>
The use of constraint-based reconstruction and analysis (COBRA) methods has become popular among systems biologists to simulate and predict the metabolic phenotypes, using genome-scale models. One of the methods is the [[flux balance analysis]] (FBA) approach, by which one can study the biochemical networks and analyze the flow of metabolites through a particular metabolic network, by optimizing the objective function of interest (e.g. maximizing biomass production to predict growth).<ref>{{Cite journal|last1=Orth|first1=Jeffrey D|last2=Thiele|first2=Ines|last3=Palsson|first3=Bernhard Ø|date=March 2010|title=What is flux balance analysis?|journal=Nature Biotechnology|language=en|volume=28|issue=3|pages=245–248|doi=10.1038/nbt.1614|issn=1087-0156|pmc=3108565|pmid=20212490}}</ref>
[[File:Toy_Model_Plot.jpg|thumb|325x325px|Plot of Concentrations vs time for the simple three protein negative feedback loop. All parameters are set to either 0 or 1 for initial conditions. The reaction is allowed to proceed until it hits equilibrium. This plot is of the change in each protein over time.]]
[[File:Toy_Model_Plot.jpg|thumb|325x325px|Plot of Concentrations vs time for the simple three protein negative feedback loop. All parameters are set to either 0 or 1 for initial conditions. The reaction is allowed to proceed until it hits equilibrium. This plot is of the change in each protein over time.]]


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{{Portal|Systems science|Biology|Evolutionary biology}}
{{Portal|Systems science|Biology|Evolutionary biology}}
{{div col}}
{{div col}}
* [[Biochemical systems equation]]
* [[Biological computation]]
* [[Biological computation]]
* [[BioSystems|BioSystems (journal)]]
* [[BioSystems|BioSystems (journal)]]
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* [[Interactome]]
* [[Interactome]]
* [[List of omics topics in biology]]
* [[List of omics topics in biology]]
* [[living systems]]
* [[List of systems biology modeling software]]
* [[Living systems]]
* [[Metabolic Control Analysis]]
* [[Metabolic network modelling]]
* [[Metabolic network modelling]]
* [[Modelling biological systems]]
* [[Modelling biological systems]]
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* [[Network biology]]
* [[Network biology]]
* [[Network medicine]]
* [[Network medicine]]
* {{annotated link|Noogenesis}}
* [[Synthetic biology]]
* [[Synthetic biology]]
* [[Systems biomedicine]]
* [[Systems biomedicine]]
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== Further reading ==
== Further reading ==
* {{cite book|last1=Klipp|first1=Edda|last2= Liebermeister|first2=Wolfram|last3=Wierling|first3=Christoph|last4=Kowald|first4=Axel|title=Systems Biology - A Textbook, 2nd edition|isbn=978-3-527-33636-4|publisher=Wiley|year=2016}}
* {{cite book|last1=Klipp|first1=Edda|last2= Liebermeister|first2=Wolfram|last3=Wierling|first3=Christoph|last4=Kowald|first4=Axel|title=Systems Biology - A Textbook, 2nd edition|isbn=978-3-527-33636-4|publisher=Wiley|year=2016}}
* {{cite book|editor=Asfar S. Azmi|title=Systems Biology in Cancer Research and Drug Discovery|isbn=978-94-007-4819-4|year=2012}}
* {{cite book|editor=Asfar S. Azmi|title=Systems Biology in Cancer Research and Drug Discovery|isbn=978-94-007-4819-4|year=2012|publisher=Springer }}
* {{cite book|last=Kitano|first=Hiroaki|author-link=Hiroaki Kitano|title=Foundations of Systems Biology|date=15 October 2001|publisher=MIT Press|isbn=978-0-262-11266-6|url-access=registration|url=https://archive.org/details/foundationsofsys00hiro}}
* {{cite book|last=Kitano|first=Hiroaki|author-link=Hiroaki Kitano|title=Foundations of Systems Biology|date=15 October 2001|publisher=MIT Press|isbn=978-0-262-11266-6|url-access=registration|url=https://archive.org/details/foundationsofsys00hiro}}
* {{cite journal|last1=Werner|first1=Eric|date=29 March 2007|title=All systems go|journal=Nature|volume=446|doi=10.1038/446493a|issue=7135|bibcode=2007Natur.446..493W|pages=493–494|doi-access=free}} provides a comparative review of three books:
* {{cite journal|last1=Werner|first1=Eric|date=29 March 2007|title=All systems go|journal=Nature|volume=446|doi=10.1038/446493a|issue=7135|bibcode=2007Natur.446..493W|pages=493–494|doi-access=free}} provides a comparative review of three books:
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==External links==
==External links==
{{Wiktionary}}
{{Wiktionary}}
*{{Commonscatinline|Systems biology}}
* [http://www.bio-physics.at/wiki/index.php?title=Biological_Systems Biological Systems in bio-physics-wiki]
*[http://www.bio-physics.at/wiki/index.php?title=Biological_Systems Biological Systems in bio-physics-wiki]


{{Biology_nav}}
{{Biology_nav}}

Latest revision as of 12:23, 17 August 2024

An illustration of the systems approach to biology

Systems biology is the computational and mathematical analysis and modeling of complex biological systems. It is a biology-based interdisciplinary field of study that focuses on complex interactions within biological systems, using a holistic approach (holism instead of the more traditional reductionism) to biological research.[1]

Particularly from the year 2000 onwards, the concept has been used widely in biology in a variety of contexts. The Human Genome Project is an example of applied systems thinking in biology which has led to new, collaborative ways of working on problems in the biological field of genetics.[2] One of the aims of systems biology is to model and discover emergent properties, properties of cells, tissues and organisms functioning as a system whose theoretical description is only possible using techniques of systems biology.[1][3] These typically involve metabolic networks or cell signaling networks.[1][4]

Overview

[edit]

Systems biology can be considered from a number of different aspects.

As a field of study, particularly, the study of the interactions between the components of biological systems, and how these interactions give rise to the function and behavior of that system (for example, the enzymes and metabolites in a metabolic pathway or the heart beats).[5][6][7]

As a paradigm, systems biology is usually defined in antithesis to the so-called reductionist paradigm (biological organisation), although it is consistent with the scientific method. The distinction between the two paradigms is referred to in these quotations: "the reductionist approach has successfully identified most of the components and many of the interactions but, unfortunately, offers no convincing concepts or methods to understand how system properties emerge ... the pluralism of causes and effects in biological networks is better addressed by observing, through quantitative measures, multiple components simultaneously and by rigorous data integration with mathematical models." (Sauer et al.)[8] "Systems biology ... is about putting together rather than taking apart, integration rather than reduction. It requires that we develop ways of thinking about integration that are as rigorous as our reductionist programmes, but different. ... It means changing our philosophy, in the full sense of the term." (Denis Noble)[7]

As a series of operational protocols used for performing research, namely a cycle composed of theory, analytic or computational modelling to propose specific testable hypotheses about a biological system, experimental validation, and then using the newly acquired quantitative description of cells or cell processes to refine the computational model or theory.[9] Since the objective is a model of the interactions in a system, the experimental techniques that most suit systems biology are those that are system-wide and attempt to be as complete as possible. Therefore, transcriptomics, metabolomics, proteomics and high-throughput techniques are used to collect quantitative data for the construction and validation of models.[10]

As the application of dynamical systems theory to molecular biology. Indeed, the focus on the dynamics of the studied systems is the main conceptual difference between systems biology and bioinformatics.[11]

As a socioscientific phenomenon defined by the strategy of pursuing integration of complex data about the interactions in biological systems from diverse experimental sources using interdisciplinary tools and personnel.[12]

History

[edit]

Although the concept of a systems view of cellular function has been well understood since at least the 1930s,[13] technological limitations made it difficult to make systems wide measurements. The advent of microarray technology in the 1990s opened up an entire new visa for studying cells at the systems level. In 2000, the Institute for Systems Biology was established in Seattle in an effort to lure "computational" type people who it was felt were not attracted to the academic settings of the university. The institute did not have a clear definition of what the field actually was: roughly bringing together people from diverse fields to use computers to holistically study biology in new ways.[14] A Department of Systems Biology at Harvard Medical School was launched in 2003.[15] In 2006 it was predicted that the buzz generated by the "very fashionable" new concept would cause all the major universities to need a systems biology department, thus that there would be careers available for graduates with a modicum of ability in computer programming and biology.[14] In 2006 the National Science Foundation put forward a challenge to build a mathematical model of the whole cell.[citation needed] In 2012 the first whole-cell model of Mycoplasma genitalium was achieved by the Covert Laboratory at Stanford University. The whole-cell model is able to predict viability of M. genitalium cells in response to genetic mutations.[16]

An earlier precursor of systems biology, as a distinct discipline, may have been by systems theorist Mihajlo Mesarovic in 1966 with an international symposium at the Case Institute of Technology in Cleveland, Ohio, titled Systems Theory and Biology. Mesarovic predicted that perhaps in the future there would be such a thing as "systems biology".[17][18] Other early precursors that focused on the view that biology should be analyzed as a system, rather than a simple collection of parts, were Metabolic Control Analysis, developed by Henrik Kacser and Jim Burns[19] later thoroughly revised,[20] and Reinhart Heinrich and Tom Rapoport,[21] and Biochemical Systems Theory developed by Michael Savageau[22][23][24]

According to Robert Rosen in the 1960s, holistic biology had become passé by the early 20th century, as more empirical science dominated by molecular chemistry had become popular.[18] Echoing him forty years later in 2006 Kling writes that the success of molecular biology throughout the 20th century had suppressed holistic computational methods.[14] By 2011 the National Institutes of Health had made grant money available to support over ten systems biology centers in the United States,[25] but by 2012 Hunter writes that systems biology still has someway to go to achieve its full potential. Nonetheless, proponents hoped that it might once prove more useful in the future.[26]

Shows trends in systems biology research. From 1992 to 2013 database development articles increased. Articles about algorithms have fluctuated but remained fairly steady. Network properties articles and software development articles have remained low but experienced an increased about halfway through the time period 1992-2013. The articles on metabolic flux analysis decreased from 1992 to 2013. In 1992 algorithms, equations, modeling and simulation articles were most cited. In 2012 the most cited were database development articles.
Shows trends in systems biology research by presenting the number of articles out of the top 30 cited systems biology papers during that time which include a specific topic[27]

An important milestone in the development of systems biology has become the international project Physiome.[citation needed]

Associated disciplines

[edit]
Overview of signal transduction pathways

According to the interpretation of systems biology as using large data sets using interdisciplinary tools, a typical application is metabolomics, which is the complete set of all the metabolic products, metabolites, in the system at the organism, cell, or tissue level.[28]

Items that may be a computer database include: phenomics, organismal variation in phenotype as it changes during its life span; genomics, organismal deoxyribonucleic acid (DNA) sequence, including intra-organismal cell specific variation. (i.e., telomere length variation); epigenomics/epigenetics, organismal and corresponding cell specific transcriptomic regulating factors not empirically coded in the genomic sequence. (i.e., DNA methylation, Histone acetylation and deacetylation, etc.); transcriptomics, organismal, tissue or whole cell gene expression measurements by DNA microarrays or serial analysis of gene expression; interferomics, organismal, tissue, or cell-level transcript correcting factors (i.e., RNA interference), proteomics, organismal, tissue, or cell level measurements of proteins and peptides via two-dimensional gel electrophoresis, mass spectrometry or multi-dimensional protein identification techniques (advanced HPLC systems coupled with mass spectrometry). Sub disciplines include phosphoproteomics, glycoproteomics and other methods to detect chemically modified proteins; glycomics, organismal, tissue, or cell-level measurements of carbohydrates; lipidomics, organismal, tissue, or cell level measurements of lipids.[citation needed]

The molecular interactions within the cell are also studied, this is called interactomics.[29] A discipline in this field of study is protein–protein interactions, although interactomics includes the interactions of other molecules.[citation needed] Neuroelectrodynamics, where the computer's or a brain's computing function as a dynamic system is studied along with its (bio)physical mechanisms;[30] and fluxomics, measurements of the rates of metabolic reactions in a biological system (cell, tissue, or organism).[28]

In approaching a systems biology problem there are two main approaches. These are the top down and bottom up approach. The top down approach takes as much of the system into account as possible and relies largely on experimental results. The RNA-Seq technique is an example of an experimental top down approach. Conversely, the bottom up approach is used to create detailed models while also incorporating experimental data. An example of the bottom up approach is the use of circuit models to describe a simple gene network.[31]

Various technologies utilized to capture dynamic changes in mRNA, proteins, and post-translational modifications. Mechanobiology, forces and physical properties at all scales, their interplay with other regulatory mechanisms;[32] biosemiotics, analysis of the system of sign relations of an organism or other biosystems; Physiomics, a systematic study of physiome in biology.

Cancer systems biology is an example of the systems biology approach, which can be distinguished by the specific object of study (tumorigenesis and treatment of cancer). It works with the specific data (patient samples, high-throughput data with particular attention to characterizing cancer genome in patient tumour samples) and tools (immortalized cancer cell lines, mouse models of tumorigenesis, xenograft models, high-throughput sequencing methods, siRNA-based gene knocking down high-throughput screenings, computational modeling of the consequences of somatic mutations and genome instability).[33] The long-term objective of the systems biology of cancer is ability to better diagnose cancer, classify it and better predict the outcome of a suggested treatment, which is a basis for personalized cancer medicine and virtual cancer patient in more distant prospective. Significant efforts in computational systems biology of cancer have been made in creating realistic multi-scale in silico models of various tumours.[34]

The systems biology approach often involves the development of mechanistic models, such as the reconstruction of dynamic systems from the quantitative properties of their elementary building blocks.[35][36][37][38] For instance, a cellular network can be modelled mathematically using methods coming from chemical kinetics[39] and control theory. Due to the large number of parameters, variables and constraints in cellular networks, numerical and computational techniques are often used (e.g., flux balance analysis).[37][39]

Bioinformatics and data analysis

[edit]

Other aspects of computer science, informatics, and statistics are also used in systems biology. These include new forms of computational models, such as the use of process calculi to model biological processes (notable approaches include stochastic π-calculus, BioAmbients, Beta Binders, BioPEPA, and Brane calculus) and constraint-based modeling; integration of information from the literature, using techniques of information extraction and text mining;[40] development of online databases and repositories for sharing data and models, approaches to database integration and software interoperability via loose coupling of software, websites and databases, or commercial suits; network-based approaches for analyzing high dimensional genomic data sets. For example, weighted correlation network analysis is often used for identifying clusters (referred to as modules), modeling the relationship between clusters, calculating fuzzy measures of cluster (module) membership, identifying intramodular hubs, and for studying cluster preservation in other data sets; pathway-based methods for omics data analysis, e.g. approaches to identify and score pathways with differential activity of their gene, protein, or metabolite members.[41] Much of the analysis of genomic data sets also include identifying correlations. Additionally, as much of the information comes from different fields, the development of syntactically and semantically sound ways of representing biological models is needed.[42]

Creating biological models

[edit]
A simple three protein negative feedback loop modeled with mass action kinetic differential equations. Each protein interaction is described by a Michaelis–Menten reaction.[43]

Researchers begin by choosing a biological pathway and diagramming all of the protein, gene, and/or metabolic pathways. After determining all of the interactions, mass action kinetics or enzyme kinetic rate laws are used to describe the speed of the reactions in the system. Using mass-conservation, the differential equations for the biological system can be constructed. Experiments or parameter fitting can be done to determine the parameter values to use in the differential equations.[44] These parameter values will be the various kinetic constants required to fully describe the model. This model determines the behavior of species in biological systems and bring new insight to the specific activities of system. Sometimes it is not possible to gather all reaction rates of a system. Unknown reaction rates are determined by simulating the model of known parameters and target behavior which provides possible parameter values.[45][43]

The use of constraint-based reconstruction and analysis (COBRA) methods has become popular among systems biologists to simulate and predict the metabolic phenotypes, using genome-scale models. One of the methods is the flux balance analysis (FBA) approach, by which one can study the biochemical networks and analyze the flow of metabolites through a particular metabolic network, by optimizing the objective function of interest (e.g. maximizing biomass production to predict growth).[46]

Plot of Concentrations vs time for the simple three protein negative feedback loop. All parameters are set to either 0 or 1 for initial conditions. The reaction is allowed to proceed until it hits equilibrium. This plot is of the change in each protein over time.

See also

[edit]

References

[edit]
  1. ^ a b c Tavassoly, Iman; Goldfarb, Joseph; Iyengar, Ravi (2018-10-04). "Systems biology primer: the basic methods and approaches". Essays in Biochemistry. 62 (4): 487–500. doi:10.1042/EBC20180003. ISSN 0071-1365. PMID 30287586. S2CID 52922135.
  2. ^ Zewail, Ahmed (2008). Physical Biology: From Atoms to Medicine. Imperial College Press. p. 339.
  3. ^ Longo, Giuseppe; Montévil, Maël (2014). Perspectives on Organisms - Springer. Lecture Notes in Morphogenesis. doi:10.1007/978-3-642-35938-5. ISBN 978-3-642-35937-8. S2CID 27653540.
  4. ^ Bu Z, Callaway DJ (2011). "Proteins MOVE! Protein dynamics and long-range allostery in cell signaling". Protein Structure and Diseases. Advances in Protein Chemistry and Structural Biology. Vol. 83. pp. 163–221. doi:10.1016/B978-0-12-381262-9.00005-7. ISBN 978-0-123-81262-9. PMID 21570668.
  5. ^ Snoep, Jacky L; Westerhoff, Hans V (2005). "From isolation to integration, a systems biology approach for building the Silicon Cell". In Alberghina, Lilia; Westerhoff, Hans V (eds.). Systems Biology: Definitions and Perspectives. Topics in Current Genetics. Vol. 13. Berlin: Springer-Verlag. pp. 13–30. doi:10.1007/b106456. ISBN 978-3-540-22968-1.
  6. ^ "Systems Biology: the 21st Century Science". Institute for Systems Biology. Retrieved 15 June 2011.
  7. ^ a b Noble, Denis (2006). The music of life: Biology beyond the genome. Oxford: Oxford University Press. p. 176. ISBN 978-0-19-929573-9.
  8. ^ Sauer, Uwe; Heinemann, Matthias; Zamboni, Nicola (27 April 2007). "Genetics: Getting Closer to the Whole Picture". Science. 316 (5824): 550–551. doi:10.1126/science.1142502. PMID 17463274. S2CID 42448991.
  9. ^ Kholodenko, Boris N; Sauro, Herbert M (2005). "Mechanistic and modular approaches to modeling and inference of cellular regulatory networks". In Alberghina, Lilia; Westerhoff, Hans V (eds.). Systems Biology: Definitions and Perspectives. Topics in Current Genetics. Vol. 13. Berlin: Springer-Verlag. pp. 357–451. doi:10.1007/b136809. ISBN 978-3-540-22968-1.
  10. ^ Chiara Romualdi; Gerolamo Lanfranchi (2009). "Statistical Tools for Gene Expression Analysis and Systems Biology and Related Web Resources". In Stephen Krawetz (ed.). Bioinformatics for Systems Biology (2nd ed.). Humana Press. pp. 181–205. doi:10.1007/978-1-59745-440-7_11. ISBN 978-1-59745-440-7.
  11. ^ Voit, Eberhard (2012). A First Course in Systems Biology. Garland Science. ISBN 9780815344674.
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