Evolutionary design principles and functional characteristics based on kingdom-specific network motifs

BACKGROUND: Network motifs within biological networks show non-random abundances in systems at different scales. Large directed protein networks at the cellular level are now well defined in several diverse species. We aimed to compare the nature of significantly observed two- and three-node network motifs across three different kingdoms (Arabidopsis thaliana for multicellular plants, Saccharomyces cerevisiae for unicellular fungi and Homo sapiens for animals). RESULTS: 'Two-node feedback' is the most significant motif in all three species. By considering the sign of each two-node feedback interaction, we examined the enrichment of the three types of two-node feedbacks [positive-positive (PP), negative-negative (NN) and positive-negative (PN)]. We found that PN is enriched in the network of A.thaliana, NN in the network of S.cerevisiae and PP and NN in the network of H.sapiens. Each feedback type has characteristic features of robustness, multistability and homeostasis. Conclusions: We suggest that amplification of particular network motifs emerges from contrasting dynamical and topological properties of the motifs, reflects the evolutionary design principles selected by the characteristic behavior of each species and provides a signature pointing to their behavior and function.     

Evolutionary theory and the foundation of moral principles

Evolutionary biology is supposed to be relevant to ethics by a number of authors. Some of them believe that it may provide and justify basic moral values. Others argue that evolutionary biology is relevant only in a negative way. They assume that it reveals the illusory nature of any attempt to justify basic moral values. In this paper one example of either approach is criticized. An analysis of examples can hardly offer sufficient grounds for a general conclusion. Nevertheless I believe that evolutionary theory is of little help when we deal with the most basic ethical questions. Three themes which are often though to provide a link between evolutionary biology and (meta)ethics — altruism, sociality and human nature — do not in fact establish that link.     

Evolutionary principles and the regulation of engineered bacteria

The introduction of engineered bacteria to the environment is being overregulated, on the basis of several assumptions: (i) the danger from deliberate introduction on a large scale is much greater than that from accidental release; (ii) the more distant the source of the DNA the greater the risk; (iii) novel organisms are likely to cause unexpected ecological damage, like that seen with native organisms transplanted to a novel location; (iv) even if the probability of harm is very small, great care must be taken because the harm might be large; (v) products of recombinant DNA must be treated differently from products of classical genetic manipulation; and (vi) our unlimited power to manipulate DNA implies an unlimited power to refashion organisms. Evolutionary principles contradict all these assumptions. Moreover, our increased power of genetic manipulation must be recognized as an expansion of the biotechnology of domestication; and unlike the physical technologies, the long history of domestication has not adventitiously created harmful by-products. I propose that in dealing with such novel and unpredictable developments it would be better to respond with speed and resilience to problems as they arise, rather than to hamper advances by clumsy regulations based on unsubstantiated guesses.     

The Landscape Game: A learning tool demonstrating landscape design principles

Summary A board game was developed for use in workshops to demonstrate some theoretical principles underpinning conservation planning at the landscape scale. The game is based on neutral landscape models and demonstrates the effects of habitat removal and arrangement on landscape connectivity for organisms with different mobility characteristics. This paper briefly describes the ecological principles underpinning the game, the equipment required to run a game session, and the rules of the game. The game was piloted in three workshops where it was played by a total of 75 people, primarily extension personnel. It proved to be an effective learning tool that was adopted by a number of the participants for their own communication activities.     

PAR polarity: From complexity to design principles

The par-titioning-defective or PAR proteins comprise the core of an essential cell polarity network that underlies polarization in a wide variety of cell types and developmental contexts. The output of this network in nearly every case is the establishment of opposing and complementary membrane domains that define a cell?s polarity axis. Yet, behind this simple pattern is a complex system of interactions, regulation and dynamic behaviors. How these various parts combine to generate polarized patterns of protein localization in cells is only beginning to become clear. This review, part of the Special Issue on Cell Polarity, aims to highlight several emerging themes and design principles that underlie the process of cell polarization by components of the PAR network.     

Building the cell: design principles of cellular architecture

The astounding structural complexity of a cell arises from the action of a relatively small number of genes, raising the question of how this complexity is achieved. Self-organizing processes combined with simple physical constraints seem to have key roles in controlling organelle size, number, shape and position, and these factors then combine to produce the overall cell architecture. By examining how these parameters are controlled in specific cell biological examples we can identify a handful of simple design principles that seem to underlie cellular architecture and assembly.     

Virus-inspired design principles of nanoparticle-based bioagents

The highly effectiveness and robustness of receptor-mediated viral invasion of living cells shed lights on the biomimetic design of nanoparticle(NP)-based therapeutics. Through thermodynamic analysis, we elucidate that the mechanisms governing both the endocytic time of a single NP and the cellular uptake can be unified into a general energy-balance framework of NP-membrane adhesion and membrane deformation. Yet the NP-membrane adhesion strength is a globally variable quantity that effectively regulates the NP uptake rate. Our analysis shows that the uptake rate interrelatedly depends on the particle size and ligand density, in contrast to the widely reported size effect. Our model predicts that the optimal radius of NPs for maximal uptake rate falls in the range of 25-30 nm, and optimally several tens of ligands should be coated onto NPs. These findings are supported by both recent experiments and typical viral structures, and serve as fundamental principles for the rational design of NP-based nanomedicine.     

Systems metabolomics: from metabolomic snapshots to design principles

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Modular design: Implementing proven engineering principles in biotechnology

Modular design is at the foundation of contemporary engineering, enabling rapid, efficient, and reproducible construction and maintenance of complex systems across applications. Remarkably, modularity has recently been discovered as a governing principle in natural biological systems from genes to proteins to complex networks within a cell and organism communities. The convergent knowledge of natural and engineered modular systems provides a key to drive modern biotechnology to address emergent challenges associated with health, food, energy, and the environment. Here, we first present the theory and application of modular design in traditional engineering fields. We then discuss the significance and impact of modular architectures on systems biology and biotechnology. Next, we focus on the very recent theoretical and experimental advances in modular cell engineering that seeks to enable rapid and systematic development of microbial catalysts capable of efficiently synthesizing a large space of useful chemicals. We conclude with an outlook towards theoretical and practical opportunities for a more systematic and effective application of modular cell engineering in biotechnology.     

自然保护区的缓冲区:模式、功能及规划原则

自然保护区是就地保护生物多样性的途径,然而在实践中逐渐暴露出了一些保护区设计方面的问题,其中最严重的是自然保护区与非自然保护区之间的过渡问题。为了解决这个问题,人们提出了在自然保护区内设立缓冲区的想法。现在缓冲区已经成为自然保护区的有机组成部分,具有生态缓冲和社会缓冲两大主要功能。本文归纳了自然保护区缓冲区的定义、模式和类型,回顾了缓冲区的发展,总结了缓冲区的规划原则。最后,我们还对国内保护区缓冲区的现状进行了讨论。     

Evolutionary principles for general frequency-dependent two-phenotype models in sexual populations

The evolutionary dynamics in general two-sex two-phenotype frequency-dependent selection models are studied with respect to underlying multi-allele one-locus genetic systems. Two classes of equilibria come into play: genotypic equilibria, with equilibrium allelic frequencies independent of the phenotype, and phenotypic equilibria, which are characterized by equal mean phenotypic fitnesses. The exact conditions for genotypic equilibria to exist and be stable and for phenotypic equilibria to exist and be evolutionarily attractive are examined. Using adequate definitions of mean fitnesses in general contexts of frequency-dependent selection in dioecious populations, we show that two phenotypes, when they can coexist in the population, tend to balance their fitnesses as far as is allowed by the genetic system as more alleles responsible for phenotype determination are introduced into the population.     

Shigella IpaA mediates actin bundling through diffusible vinculin oligomers with activation imprint

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Process optimization using combinatorial design principles: parallel synthesis and design of experiment methods

The use of parallel synthesis techniques with statistical design of experiment (DoE) methods is a powerful combination for the optimization of chemical processes. Advances in parallel synthesis equipment and easy to use software for statistical DoE have fueled a growing acceptance of these techniques in the pharmaceutical industry. As drug candidate structures become more complex at the same time that development timelines are compressed, these enabling technologies promise to become more important in the future.     

The imprint of codons on protein structure

The "central dogma" of biology outlines the unidirectional flow of interpretable data from genetic sequence to protein sequence. This has led to the idea that a protein's structure is dependent only on its amino acid sequence and not its genetic sequence. Recently, however, a more than transient link between the coding genetic sequence and the protein structure has become apparent. The two interact at the ribosome via the process of co-translational protein folding. Evidence for co-translational folding is growing rapidly, but the influence of codons on the protein structure attained is still highly contentious. It is theorised that the speed of codon translation modulates the time available for protein folding and hence the protein structure. Here, past and present research regarding synonymous codons and codon translation speed are reviewed within the context of protein structure attainment.     

Evolutionary principles for generating protein mimetics: directed assembly of peptide loops on topological templates

A novel methodology for the reversible competitive condensation of peptide loops to chemoreactive topological templates is presented.