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Hlavacek, William Scott; Gnanakaran, Sandrasegaram; Munsky, Brian; Wall, Michael E.
Los Alamos National Laboratory (LANL), Los Alamos, NM (United States). Funding organisation: USDOE (United States)2015
Los Alamos National Laboratory (LANL), Los Alamos, NM (United States). Funding organisation: USDOE (United States)2015
AbstractAbstract
[en] This Special Issue, edited by Ilya Nemenman, celebrates the Eighth q-bio Conference, which took place in Santa Fe, New Mexico from August 13 to 16, 2014. Here, it consists of a commentary, two reviews, and five primary reports, which represent ideas and work discussed at the meeting.
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LA-UR--15-28320; OSTIID--1408830; AC52-06NA25396; Available from http://www.osti.gov/pages/servlets/purl/1408830; DOE Accepted Manuscript full text, or the publishers Best Available Version will be available free of charge after the embargo period; Country of input: United States
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Journal Article
Journal
Physical Biology (Online); ISSN 1478-3975;
; v. 12(6); vp

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Lobanov, Michail Yu; Galzitskaya, Oxana V, E-mail: ogalzit@vega.protres.ru2011
AbstractAbstract
[en] Intrinsically disordered regions serve as molecular recognition elements, which play an important role in the control of many cellular processes and signaling pathways. It is useful to be able to predict positions of disordered residues and disordered regions in protein chains using protein sequence alone. A new method (IsUnstruct) based on the Ising model for prediction of disordered residues from protein sequence alone has been developed. According to this model, each residue can be in one of two states: ordered or disordered. The model is an approximation of the Ising model in which the interaction term between neighbors has been replaced by a penalty for changing between states (the energy of border). The IsUnstruct has been compared with other available methods and found to perform well. The method correctly finds 77% of disordered residues as well as 87% of ordered residues in the CASP8 database, and 72% of disordered residues as well as 85% of ordered residues in the DisProt database
Source
S1478-3975(11)69688-4; Available from http://dx.doi.org/10.1088/1478-3975/8/3/035004; Country of input: International Atomic Energy Agency (IAEA)
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Journal Article
Journal
Physical Biology (Online); ISSN 1478-3975;
; v. 8(3); [9 p.]

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Hashimoto, Kosuke; Nishi, Hafumi; Bryant, Stephen; Panchenko, Anna R, E-mail: panch@ncbi.nlm.nih.gov2011
AbstractAbstract
[en] Many soluble and membrane proteins form homooligomeric complexes in a cell which are responsible for the diversity and specificity of many pathways, may mediate and regulate gene expression, activity of enzymes, ion channels, receptors, and cell adhesion processes. The evolutionary and physical mechanisms of oligomerization are very diverse and its general principles have not yet been formulated. Homooligomeric states may be conserved within certain protein subfamilies and might be important in providing specificity to certain substrates while minimizing interactions with other unwanted partners. Moreover, recent studies have led to a greater awareness that transitions between different oligomeric states may regulate protein activity and provide the switch between different pathways. In this paper we summarize the biological importance of homooligomeric assemblies, physico-chemical properties of their interfaces, experimental and computational methods for their identification and prediction. We particularly focus on homooligomer evolution and describe the mechanisms to develop new specificities through the formation of different homooligomeric complexes. Finally, we discuss the possible role of oligomeric transitions in the regulation of protein activity and compile a set of experimental examples with such regulatory mechanisms
Source
S1478-3975(11)72613-3; Available from http://dx.doi.org/10.1088/1478-3975/8/3/035007; Country of input: International Atomic Energy Agency (IAEA)
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Journal Article
Journal
Physical Biology (Online); ISSN 1478-3975;
; v. 8(3); [9 p.]

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INIS VolumeINIS Volume
INIS IssueINIS Issue
AbstractAbstract
[en] Circulating tumor cells (CTCs) have been implicated as a population of cells that may seed metastasis and venous thromboembolism (VTE), two major causes of mortality in cancer patients. Thus far, existing CTC detection technologies have been unable to reproducibly detect CTC aggregates in order to address what contribution CTC aggregates may make to metastasis or VTE. We report here an enrichment-free immunofluorescence detection method that can reproducibly detect and enumerate homotypic CTC aggregates in patient samples. We identified CTC aggregates in 43% of 86 patient samples. The fraction of CTC aggregation was investigated in blood draws from 24 breast, 14 non-small cell lung, 18 pancreatic, 15 prostate stage IV cancer patients and 15 normal blood donors. Both single CTCs and CTC aggregates were measured to determine whether differences exist in the physical characteristics of these two populations. Cells contained in CTC aggregates had less area and length, on average, than single CTCs. Nuclear to cytoplasmic ratios between single CTCs and CTC aggregates were similar. This detection method may assist future studies in determining which population of cells is more physically likely to contribute to metastasis and VTE
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S1478-3975(12)97748-1; Available from http://dx.doi.org/10.1088/1478-3975/9/1/016001; Country of input: International Atomic Energy Agency (IAEA)
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Journal Article
Journal
Physical Biology (Online); ISSN 1478-3975;
; v. 9(1); [6 p.]

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Tsukanov, R; Reshes, G; Carmon, G; Feingold, M; Fischer-Friedrich, E; Gov, N S; Fishov, I, E-mail: mario@bgu.ac.il2011
AbstractAbstract
[en] Bacterial cell division takes place in three phases: Z-ring formation at midcell, followed by divisome assembly and building of the septum per se. Using time-lapse microscopy of live bacteria and a high-precision cell edge detection method, we have previously found the true time for the onset of septation, τ_c, and the time between consecutive divisions, τ_g. Here, we combine the above method with measuring the dynamics of the FtsZ-GFP distribution in individual Escherichia coli cells to determine the Z-ring positioning time, τ_z. To analyze the FtsZ-GFP distribution along the cell, we used the integral fluorescence profile (IFP), which was obtained by integrating the fluorescence intensity across the cell width. We showed that the IFP may be approximated by an exponential peak and followed the peak evolution throughout the cell cycle, to find a quantitative criterion for the positioning of the Z-ring and hence the value of τ_z. We defined τ_z as the transition from oscillatory to stable behavior of the mean IFP position. This criterion was corroborated by comparison of the experimental results to a theoretical model for the FtsZ dynamics, driven by Min oscillations. We found that τ_z < τ_c for all the cells that were analyzed. Moreover, our data suggested that τ_z is independent of τ_c, τ_g and the cell length at birth, L_0. These results are consistent with the current understanding of the Z-ring positioning and cell septation processes
Source
S1478-3975(11)01873-5; Available from http://dx.doi.org/10.1088/1478-3975/8/6/066003; Country of input: International Atomic Energy Agency (IAEA)
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Journal Article
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Physical Biology (Online); ISSN 1478-3975;
; v. 8(6); [13 p.]

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AbstractAbstract
[en] In shallow temperature gradients, changes in temperature that bacteria experience occur over long time scales. Therefore, slow processes such as adaptation, metabolism, chemical secretion and even gene expression become important. Since these are cellular processes, the cell density is an important parameter that affects the bacteria's response. We find that there are four density regimes with distinct behaviors. At low cell density, bacteria do not cause changes in their chemical environment; however, their response to the temperature gradient is strongly influenced by it. In the intermediate cell-density regime, the consumption of nutrients becomes significant and induces a gradient of nutrients opposing the temperature gradient due to higher consumption rate at the high temperature. This causes the bacteria to drift toward low temperature. In the high cell-density regime, interactions among bacteria due to secretion of an attractant lead to a strong local accumulation of bacteria. This together with the gradient of nutrients, resulted from the differential consumption rate, creates a fast propagating pulse of bacterial density. These observations are a result of classical nonlinear population dynamics. At extremely high cell density, a change in the physiological state of the bacteria is observed. The bacteria, at the individual level, become cold seeking. This appears initially as a result of a change in the methylation level of the two most abundant sensing receptors, Tsr and Tar. It is further enforced at an even higher cell density by a change in the expression level of these receptors. (perspective)
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S1478-3975(11)86980-3; Available from http://dx.doi.org/10.1088/1478-3975/8/6/063001; Country of input: International Atomic Energy Agency (IAEA)
Record Type
Journal Article
Journal
Physical Biology (Online); ISSN 1478-3975;
; v. 8(6); [8 p.]

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Szabó, A; Rupp, P A; Rongish, B J; Little, C D; Czirók, A, E-mail: aczirok@kumc.edu2011
AbstractAbstract
[en] Extracellular matrix (ECM) movements and rearrangements were studied in avian embryos during early stages of development. We show that the ECM moves as a composite material, whereby distinct molecular components as well as spatially separated layers exhibit similar displacements. Using scanning wide field and confocal microscopy we show that the velocity field of ECM displacement is smooth in space and that ECM movements are correlated even at locations separated by several hundred micrometers. Velocity vectors, however, strongly fluctuate in time. The autocorrelation time of the velocity fluctuations is less than a minute. Suppression of the fluctuations yields a persistent movement pattern that is shared among embryos at equivalent stages of development. The high resolution of the velocity fields allows a detailed spatio-temporal characterization of important morphogenetic processes, especially tissue dynamics surrounding the embryonic organizer (Hensen's node)
Source
S1478-3975(11)83681-2; Available from http://dx.doi.org/10.1088/1478-3975/8/4/045006; Country of input: International Atomic Energy Agency (IAEA)
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Journal Article
Journal
Physical Biology (Online); ISSN 1478-3975;
; v. 8(4); [12 p.]

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Elgart, Vlad; Jia, Tao; Fenley, Andrew T; Kulkarni, Rahul, E-mail: elgart@vt.edu, E-mail: kulkarni@vt.edu2011
AbstractAbstract
[en] The intrinsic stochasticity of gene expression can lead to large variability in protein levels for genetically identical cells. Such variability in protein levels can arise from infrequent synthesis of mRNAs which in turn give rise to bursts of protein expression. Protein expression occurring in bursts has indeed been observed experimentally and recent studies have also found evidence for transcriptional bursting, i.e. production of mRNAs in bursts. Given that there are distinct experimental techniques for quantifying the noise at different stages of gene expression, it is of interest to derive analytical results connecting experimental observations at different levels. In this work, we consider stochastic models of gene expression for which mRNA and protein production occurs in independent bursts. For such models, we derive analytical expressions connecting protein and mRNA burst distributions which show how the functional form of the mRNA burst distribution can be inferred from the protein burst distribution. Additionally, if gene expression is repressed such that observed protein bursts arise only from single mRNAs, we show how observations of protein burst distributions (repressed and unrepressed) can be used to completely determine the mRNA burst distribution. Assuming independent contributions from individual bursts, we derive analytical expressions connecting means and variances for burst and steady-state protein distributions. Finally, we validate our general analytical results by considering a specific reaction scheme involving regulation of protein bursts by small RNAs. For a range of parameters, we derive analytical expressions for regulated protein distributions that are validated using stochastic simulations. The analytical results obtained in this work can thus serve as useful inputs for a broad range of studies focusing on stochasticity in gene expression
Source
S1478-3975(11)80532-7; Available from http://dx.doi.org/10.1088/1478-3975/8/4/046001; Country of input: International Atomic Energy Agency (IAEA)
Record Type
Journal Article
Journal
Physical Biology (Online); ISSN 1478-3975;
; v. 8(4); [9 p.]

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Sun, Tingzhe; Zhu, Feng; Shen, Pingping; Yuan, Ruoshi; Xu, Wei, E-mail: ppshen@nju.edu.cn2010
AbstractAbstract
[en] The tumor suppressor p53 coordinates many attributes of cellular processes via interlocked feedback loops. To understand the biological implications of feedback loops in a p53 system, a two-component model which encompasses essential feedback loops was constructed and further explored. Diverse bifurcation properties, such as bistability and oscillation, emerge by manipulating the feedback strength. The p53-mediated MDM2 induction dictates the bifurcation patterns. We first identified irradiation dichotomy in p53 models and further proposed that bistability and oscillation can behave in a coordinated manner. Further sensitivity analysis revealed that p53 basal production and MDM2-mediated p53 degradation, which are central to cellular control, are most sensitive processes. Also, we identified that the much more significant variations in amplitude of p53 pulses observed in experiments can be derived from overall amplitude parameter sensitivity. The combined approach with bifurcation analysis, stochastic simulation and sampling-based sensitivity analysis not only gives crucial insights into the dynamics of the p53 system, but also creates a fertile ground for understanding the regulatory patterns of other biological networks
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Source
S1478-3975(10)55739-X; Available from http://dx.doi.org/10.1088/1478-3975/7/3/036008; Country of input: International Atomic Energy Agency (IAEA)
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Journal Article
Journal
Physical Biology (Online); ISSN 1478-3975;
; v. 7(3); [11 p.]

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Fraiman, Daniel; Dawson, Silvina Ponce, E-mail: dfraiman@udesa.edu.ar, E-mail: silvina@df.uba.ar2014
AbstractAbstract
[en] Puffs are localized Ca"2"+ signals that arise in oocytes in response to inositol 1,4,5-trisphosphate (IP_3). They are the result of the liberation of Ca"2"+ from the endoplasmic reticulum through the coordinated opening of IP_3 receptor/channels clustered at a functional release site. The presence of buffers that trap Ca"2"+ provides a mechanism that enriches the spatio–temporal dynamics of cytosolic calcium. The expression of different types of buffers along the cell's life provides a tool with which Ca"2"+ signals and their responses can be modulated. In this paper we extend the stochastic model of a cluster of IP_3R-Ca"2"+ channels introduced previously to elucidate the effect of buffers on sequences of puffs at the same release site. We obtain analytically the probability laws of the interpuff time and of the number of channels that participate of the puffs. Furthermore, we show that under typical experimental conditions the effect of buffers can be accounted for in terms of a simple inhibiting function. Hence, by exploring different inhibiting functions we are able to study the effect of a variety of buffers on the puff size and interpuff time distributions. We find the somewhat counter-intuitive result that the addition of a fast Ca"2"+ buffer can increase the average number of channels that participate of a puff. (paper)
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Available from http://dx.doi.org/10.1088/1478-3975/11/1/016007; Country of input: International Atomic Energy Agency (IAEA)
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Journal Article
Journal
Physical Biology (Online); ISSN 1478-3975;
; v. 11(1); [11 p.]

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