Cue-Recruitment for Extrinsic Signals after Training with Low Information Stimuli

Cue-recruitment occurs when a previously ineffective signal comes to affect the perceptual appearance of a target object, in a manner similar to the trusted cues with which the signal was put into correlation during training [1], [2]. Jain, Fuller and Backus [3] reported that extrinsic signals, those not carried by the target object itself, were not recruited even after extensive training. However, recent studies have shown that training using weakened trusted cues can facilitate recruitment of intrinsic signals [4]–[7]. The current study was designed to examine whether extrinsic signals can be recruited by putting them in correlation with weakened trusted cues. Specifically, we tested whether an extrinsic visual signal, the rotary motion direction of an annulus of random dots, and an extrinsic auditory signal, direction of an auditory pitch glide, can be recruited as cues for the rotation direction of a Necker cube. We found learning, albeit weak, for visual but not for auditory signals. These results extend the generality of the cue-recruitment phenomenon to an extrinsic signal and provide further evidence that the visual system learns to use new signals most quickly when other, long-trusted cues are unavailable or unreliable.     

In Vivo Haploid Production in Crop Plants: Methods and Challenges

Plant Molecular Biology Reporter - Doubled haploids offer a rapid method of producing homozygous lines for accelerated breeding of varieties and hybrids necessary to address the food demands of the...     

Centromeric histone H3 protein: from basic study to plant breeding applications

Centromere is the defining unit of a chromosome where kinetochore complex assembles and facilitates chromosome segregation. Centromeres contain unique repetitive sequences and are enriched with transposons and retrotransposons. Although how centromere is determined is still not clearly understood, binding of a key protein, namely, the Centromeric Histone H3 (CENH3) to centromeric repetitive DNA sequences has been found to be critical for the specification of centromere. Hence, centromeres are said to be epigenetically specified by CENH3. Despite considerable variation in size and sequence, CENH3 protein shows significant conservation of structure and function. CENH3 disruption or overexpression shows severe defects in spindle fiber attachment and ultimately leads to embryo lethality. Basic studies on complementation of CENH3 in Arabidopsis thaliana have led to the development of a novel method of haploid production through selective elimination of one set of parental chromosomes in the zygote. These findings have also shed new light on selective loss of chromosomes in interspecific crosses of Hordeum vulgare × H. bulbosum. Here, we briefly review unique features of CENH3 and discuss the new plant breeding opportunities that have emerged from the study of CENH3.     

Modeling multi-robot task allocation with limited information as global game

Continuous response threshold functions to coordinate collaborative tasks in multi-agent systems are commonly employed models in a number of fields including ethology, economics, and swarm robotics. Although empirical evidence exists for the response threshold model in predicting and matching swarm behavior for social insects, there has been no formal argument as to why natural swarms use this approach and why it should be used for engineering artificial ones. In this paper, we show, by formulating task allocation as a global game, that continuous response threshold functions used for communication-free task assignment result in system level Bayesian Nash equilibria. Building up on these results, we show that individual agents not only do not need to communicate with each other, but also do not need to model each other’s behavior, which makes this coordination mechanism accessible to very simple agents, suggesting a reason for their prevalence in nature and motivating their use in an engineering context.     

An Evolutionarily Conserved Family of Virion Tail Needles Related to Bacteriophage P22 gp26: Correlation between Structural Stability and Length of the α-Helical Trimeric Coiled Coil

Bacteriophages of the Podoviridae family use short noncontractile tails to inject their genetic material into Gram-negative bacteria. In phage P22, the tail contains a thin needle, encoded by the phage gene 26, which is essential both for stabilization and for ejection of the packaged viral genome. Bioinformatic analysis of the N-terminal domain of gp26 (residues 1-60) led us to identify a family of genes encoding putative homologues of the tail needle gp26. To validate this idea experimentally and to explore their diversity, we cloned the gp26-like gene from phages HK620, Sf6 and HS1, and characterized these gene products in solution. All gp26-like factors contain an elongated α-helical coiled-coil core consisting of repeating, adjacent trimerization heptads and form trimeric fibers with length ranging between about 240 to 300 Å. gp26 tail needles display a high level of structural stability in solution, with T_m (temperature of melting) between 85 and 95 °C. To determine how the structural stability of these phage fibers correlates with the length of the α-helical core, we investigated the effect of insertions and deletions in the helical core. In the P22 tail needle, we identified an 85-residue-long helical domain, termed MiCRU (minimal coiled-coil repeat unit), that can be inserted in-frame inside the gp26 helical core, preserving the straight morphology of the fiber. Likewise, we were able to remove three quarters of the helical core of the HS1 tail needle, minimally decreasing the stability of the fiber. We conclude that in the gp26 family of tail needles, structural stability increases nonlinearly with the length of the α-helical core. Thus, the overall stability of these bacteriophage fibers is not solely dependent on the number of trimerization repeats in the α-helical core.     

Comparative modeling of retinol-binding protein-3 and retinal S-antigen in Eales’ disease and prediction of their binding sites using computational methods

Retinal S-antigen and interphotoreceptor retinoid-binding protein-3 play a significant role in the etiopathogenesis of Eales' disease. Protein 3D structures are functionally very important and play a significant role in progression of the disease, hence these 3D structures are better target for further drug designing and relative studies. We developed 3D model structure of retinol-binding protein-3 and retinal S-antigen protein of human involved in Eales' disease. Functional site prediction is a very important and related step; hence, in the current course of analysis, we predicted putative functional site residues in the target proteins. Molecular models of these proteins of Eales' disease as documented in this study may provide a valuable aid for designing an inhibitor or better ligand against Eales' disease and could play a significant role in drug design.     

Functional expression of the human breast cancer resistance protein in Pichia pastoris

We report functional expression of BCRP in Pichia pastoris in which BCRP was produced as a 62 kDa underglycosylated protein. BCRP expression level in P. pastoris was comparable to that in HEK cells. The basal BCRP ATPase activity in the yeast membranes was approximately 40-80 nmol Pi/min/mg protein, which can be modulated by known BCRP substrates and inhibitors. Photolabeling of BCRP with 8-azido[alpha-32P]ATP was dependent preferentially on the presence of Co2+ than Mg2+ and could be inhibited by a molar excess of ATP. Vanadate-induced trapping of 8-azido[alpha-32P]ADP by BCRP was much more significant in the presence of Co2+ than that with Mg2+. The Km and Vmax values of BCRP for [3H]E1S transport were 3.6+/-0.3 microM and 55.2+/-1.6 pmol/min/mg protein, respectively. This efficient and cost-effective expression system should facilitate large scale production and purification of BCRP for further structural and functional analyses.