A peculiar negative correlation in Oenothera hybrids

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A peculiar negative correlation in Oenothera hybrids

     

A peculiar negative correlation in Oenothera hybrids

Journal of Genetics -     

Choosing negative examples for the prediction of protein-protein interactions

The protein-protein interaction networks of even well-studied model organisms are sketchy at best, highlighting the continued need for computational methods to help direct experimentalists in the search for novel interactions. This need has prompted the development of a number of methods for predicting protein-protein interactions based on various sources of data and methodologies. The common method for choosing negative examples for training a predictor of protein-protein interactions is based on annotations of cellular localization, and the observation that pairs of proteins that have different localization patterns are unlikely to interact. While this method leads to high quality sets of non-interacting proteins, we find that this choice can lead to biased estimates of prediction accuracy, because the constraints placed on the distribution of the negative examples makes the task easier. The effects of this bias are demonstrated in the context of both sequence-based and non-sequence based features used for predicting protein-protein interactions.     

Uniform binding and negative catalysis at the origin of enzymes

Enzymes are well known for their catalytic abilities, some even reaching “catalytic perfection” in the sense that the reaction they catalyze has reached the physical bound of the diffusion rate. However, our growing understanding of enzyme superfamilies has revealed that only some share a catalytic chemistry while others share a substrate‐handle binding motif, for example, for a particular phosphate group. This suggests that some families emerged through a “substrate‐handle‐binding‐first” mechanism (“binding‐first” for brevity) instead of “chemistry‐first” and we are, therefore, left to wonder what the role of non‐catalytic binders might have been during enzyme evolution. In the last of their eight seminal, back‐to‐back articles from 1976, John Albery and Jeremy Knowles addressed the question of enzyme evolution by arguing that the simplest mode of enzyme evolution is what they defined as “uniform binding” (parallel stabilization of all enzyme‐bound states to the same degree). Indeed, we show that a uniform‐binding proto‐catalyst can accelerate a reaction, but only when catalysis is already present, that is, when the transition state is already stabilized to some degree. Thus, we sought an alternative explanation for the cases where substrate‐handle‐binding preceded any involvement of a catalyst. We find that evolutionary starting points that exhibit negative catalysis can redirect the reaction''s course to a preferred product without need for rate acceleration or product release; that is, if they do not stabilize, or even destabilize, the transition state corresponding to an undesired product. Such a mechanism might explain the emergence of “binding‐first” enzyme families like the aldolase superfamily.     

Artefactual origin of biphasic cortical spike-LFP correlation

Electrophysiological data acquisition systems introduce various distortions into the signals they record. While such distortions were discussed previously, their effects are often not appreciated. Here I show that the biphasic shape of cortical spike-triggered LFP average (stLFP), reported in multiple studies, is likely an artefact introduced by high-pass filter of the neural data acquisition system when the actual stLFP has a single trough around the zero lag.     

Analysing the origin of long-range interactions in proteins using lattice models

Background  

Long-range communication is very common in proteins but the physical basis of this phenomenon remains unclear. In order to gain insight into this problem, we decided to explore whether long-range interactions exist in lattice models of proteins. Lattice models of proteins have proven to capture some of the basic properties of real proteins and, thus, can be used for elucidating general principles of protein stability and folding.     

On the origin of plastids

The buoyant density in CsCl of ribosomes from chloroplasts of the green algaChlorella pyrenoidosa and two species of higher plants,Pisum sativum andChenopodium album, has been studied. From the relative protein content it was calculated that 70S ribosomes from chloroplasts are much smaller than 80S cytoplasmic ribosomes (3.0–3.1×10⁶ and 4.0×10⁶ daltons) and slightly larger than 70S ribosomes from abcteriaE. coli 2.5×10⁶ daltons). Chloroplast ribosomes from pea seedlings were analyzed by two-dimensional polyacrylamide gel electrophoresis. They appear to contain 71 proteins. This indicates that chloroplast ribosomes contain a larger number of proteins than do the ribosomes fromE. coli and other species of Enterobacteriaceae. Further study will permit a probable evaluation of the validity of Mereschkowsky's hypothesis that the photosynthetic plastids of eukaryotic plant cells are the evolutionary descendants of endosymbiotic blue-green algae.     

On the origin of feathers

The appearance of feathers defines the appearance of birds. A number of changes defined, preceded or accompanied the event. The changes were hierarchical in nature and included revolutions in genomic organization (i.e., HOX and the feather keratin genes), protein sequence and shape, the large scale organization of proteins into filaments, and in the geometry of the cells and their roles in the follicle. Changes at each of these levels differ or produced different products than found in its analog in reptiles. They are essentially unique to birds and produced an evolutionary novelty. I used analysis of extant structure and information on development to reconstruct key events in the evolution of feathers. The ancestral reptilian epidermal structure, while probably a scale or tubercles, is still unidentified. The structural genes of feather proteins (φ-keratin) are tandem repeats probably assembled from pre-existing exons. They are unlike the alpha-keratin of vertebrate soft epidermis. Amino-acid composition, shape, and behavior of feather keratins are unique among vertebrates. The 3-dimensional organization of the follicle and the developmental processes are also unique. Although we lack a complete understanding of the appearance and early role of feathers, they are clearly the results of novel events.     

On the origin of differentiation

Following the origin of multicellularity in many groups of primitive organisms there evolved more than one cell type. It has been assumed that this early differentiation is related to size — the larger the organism the more cell types. Here two very different kinds of organisms are considered: the volvocine algae that become multicellular by growth, and the cellular slime moulds that become multicellular by aggregation. In both cases there are species that have only one cell type and others that have two. It has been possible to show that there is a perfect correlation with size: the forms with two cell types are significantly larger than those with one. Also in both groups there are forms of intermediate size that will vary from one to two cell types depending on the size of the individuals, suggesting a form of quorum sensing. These observations reinforce the view that size plays a critical role in influencing the degree of differentiation.     

On the origin of neurons

A report on the conference 'Neurogenesis 2007', Tokyo, Japan, 15-16 May 2007.     

On the origin of photophosphorylation

A model based on quinol phosphates is proposed for the origin of photophosphorylation. This model is divided into three time periods. In the early period, when the primitive earth was under reducing conditions, quinol phosphates were produced through quinol radical intermediates formed by the activation of hydroquinones with ultraviolet light. Phosphorylation of a number of acceptor molecules including inorganic orthophosphate and adenosine diphosphate occurred when quinol phosphate was oxidized by Fe⁺³ or a water soluble iron-sulfur complex. After the appearance of a rudimentary ozone layer (middle period), ultraviolet light was no longer an important factor in primordial chemistry. Quinol phosphates were then produced by visible light activation of porphyrin-quinone charge transfer complexes. In the presence of light, electrons from H₂S, H₂ and several reduced organic compounds were transfered through the porphyrin to quinone yielding the quinol radical. Again, quinol phosphate was produced from breakdown of the free radical. Phosphorylation of a number of acceptor molecules was achieved when quinol phosphates were oxidized by the iron-sulfur complexes. Evolutionary pressure to increase the efficiency of these reactions resulted in the electron donor-porphyrin-quinone-iron-sulfur complex becoming more lipophilic and thus associated with the protomembrane of the evolving protocell. In the late period the protomembrane became more sophisticated and quinone was replaced as the primary electron acceptor in the photoprocess by one of the iron-sulfur complexes originally present as oxidizing agents for the quinol phosphates. Quinones eventually lost their role as phosphorylating agents and became only electron and proton shuttles in the evolving electron transport chain. The protocell evolved the ability to use water as the electron donor as the relative roles of iron and quinone in the photoprocess switched.     

On the origin of life

On the basis of the recently proposed new fundamental equation of mathematical biophysics, a suggestion is made for a theory of the formation of a primitive cell from nonliving material. The discussion includes a suggestion for a quantitative formulation of the degree of biological organization. It is shown that according to the fundamental equation of mathematical biophysics, organization of the nonliving material may spontaneously increase under certain conditions, leading to a formation of a primitive organism. This process however, is a very slow one, requiring time intervals of several years or even decades. This may account for the failure in observing or artificially producing spontaneous generation.     

On the origin of prokaryotes

It has been a tacit assumption of evolutionary theory that the closest surviving relatives of the first cellular organisms are to be found among prokaryotes. This paper draws attention to the fact that many stages of evolution appear to have been accompanied by physical loss of superfluous DNA. It is postulated that the genomes of prokaryotes—where almost every gene is represented by one copy only—represent the results of this process carried to its extreme. On this basis certain features of very early evolution which have been eliminated from prokaryotes may survive in eukaryotes. If correct, the hypothesis would require a careful re-evaluation of the assumptions underlying use of some sequence data to construct phylogenetic trees.