8,564 research outputs found
Heterogeneous popularity of metabolic reactions from evolution
The composition of cellular metabolism is different across species. Empirical
data reveal that bacterial species contain similar numbers of metabolic
reactions but that the cross-species popularity of reactions is so heterogenous
that some reactions are found in all the species while others are in just few
species, characterized by a power-law distribution with the exponent one.
Introducing an evolutionary model concretizing the stochastic recruitment of
chemical reactions into the metabolism of different species at different times
and their inheritance to descendants, we demonstrate that the exponential
growth of the number of species containing a reaction and the saturated
recruitment rate of brand-new reactions lead to the empirically identified
power-law popularity distribution. Furthermore, the structural characteristics
of metabolic networks and the species' phylogeny in our simulations agree well
with empirical observations.Comment: Main: 5 pages, 4 figures, Supplemental Material: 4 pages, 6 figure
Comparing the Heterogeneity of Copper-Binding Characteristics for Two Different-Sized Soil Humic Acid Fractions Using Fluorescence Quenching Combined with 2D-COS
Heterogeneous distributions of copper-binding characteristics were compared for two ultrafiltered size fractions of a soil HA using fluorescence quenching combined with two-dimensional correlation spectroscopy (2D-COS). The apparent shapes of the original synchronous fluorescence spectra and the extent of the fluorescence quenching upon the addition of copper were similar for the two fractions. The stability constants calculated at their highest peaks were not significantly different. However, the 2D-COS results revealed that the fluorescence quenching behaviors were strongly affected by the associated wavelengths and the fraction's size. The spectral change preferentially occurred in the wavelength order of 467 nm → 451 nm → 357 nm for the 1–10 K fraction and of 376 nm → 464 nm for the >100 K fraction. The extent of the binding affinities exactly followed the sequential orders interpreted from the 2D-COS, and they exhibited the distinctive ranges of the logarithmic values from 5.86 to 4.91 and from 6.48 to 5.95 for the 1–10 K and the >100 K fractions, respectively. Our studies demonstrated that fluorescence quenching combined with 2D-COS could be successfully utilized to give insight into the chemical heterogeneity associated with metal-binding sites within the relatively homogeneous HA size fractions
Correlation-enhanced viable core in metabolic networks
Cellular ingredient concentrations can be stabilized by adjusting generation
and consumption rates through multiple pathways. To explore the portion of
cellular metabolism equipped with multiple pathways, we categorize individual
metabolic reactions and compounds as viable or inviable: A compound is viable
if processed by two or more reactions, and a reaction is viable if all of its
substrates and products are viable. Using this classification, we identify the
maximal subnetwork of viable nodes, referred to as the {\it viable core}, in
bipartite metabolic networks across thousands of species. The obtained viable
cores are remarkably larger than those in degree-preserving randomized
networks, while their broad degree distributions commonly enable the viable
cores to shrink gradually as reaction nodes are deleted. We demonstrate that
the positive degree-degree correlations of the empirical networks may underlie
the enlarged viable cores compared to the randomized networks. By investigating
the relation between degree and cross-species frequency of metabolic compounds
and reactions, we elucidate the evolutionary origin of the correlations.Comment: 8 pages, 4 figure
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