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Yeast Genome (yeast + genome)

Distribution by Scientific Domains
Life Sciences40%

Selected Abstracts

Nonparametric Inference for Local Extrema with Application to Oligonucleotide Microarray Data in Yeast Genome

BIOMETRICS, Issue 2 2006
Peter X.-K.
Summary Identifying local extrema of expression profiles is one primary objective in some cDNA microarray experiments. To study the replication dynamics of the yeast genome, for example, local peaks of hybridization intensity profiles correspond to putative replication origins. We propose a nonparametric kernel smoothing (NKS) technique to detect local hybridization intensity extrema across chromosomes. The novelty of our approach is that we base our inference procedures on equilibrium points, namely those locations at which the first derivative of the intensity curve is zero. The proposed smoothing technique provides both point and interval estimation for the location of local extrema. Also, this technique can be used to test for the hypothesis of either one or multiple suspected locations being the true equilibrium points. We illustrate the proposed method on a microarray data set from an experiment designed to study the replication origins in the yeast genome, in that the locations of autonomous replication sequence (ARS) elements are identified through the equilibrium points of the smoothed intensity profile curve. Our method found a few ARS elements that were not detected by the current smoothing methods such as the Fourier convolution smoothing. [source]

VDE-initiated intein homing in Saccharomyces cerevisiae proceeds in a meiotic recombination-like manner

GENES TO CELLS, Issue 7 2003
Tomoyuki Fukuda
Background: Inteins and group I introns found in prokaryotic and eukaryotic organisms occasionally behave as mobile genetic elements. During meiosis of the yeast Saccharomyces cerevisiae, the site-specific endonuclease encoded by VMA1 intein, VDE, triggers a single double-strand break (DSB) at an inteinless allele, leading to VMA1 intein homing. Besides the accumulating information on the in vitro activity of VDE, very little has been known about the molecular mechanism of intein homing in yeast nucleus. Results: We developed an assay to detect the product of VMA1 intein homing in yeast genome. We analysed mutant phenotypes of RecA homologs, Rad51p and Dmc1p, and their interacting proteins, Rad54p and Tid1p, and found that they all play critical roles in intein inheritance. The absence of DSB end processing proteins, Sae2p and those in the Mre11-Rad50-Xrs2 complex, also causes partial reduction in homing efficiency. As with meiotic recombination, crossover events are frequently observed during intein homing. We also observed that the absence of premeiotic DNA replication caused by hydroxyurea (HU) or clb5, clb6, mutation reduces VDE-mediated DSBs. Conclusion: The repairing system working in intein homing shares molecular machinery with meiotic recombination induced by Spo11p. Moreover, like Spo11p-induced DNA cleavage, premeiotic DNA replication is a prerequisite for a VDE-induced DSB. VMA1 intein thus utilizes several host factors involved in meiotic and recombinational processes to spread its genetic information and guarantee its progeny through establishment of a parasitic relationship with the organism. [source]

Gene expression study of Saccharomyces cerevisiae under changing growth conditions

JOURNAL OF CHEMICAL TECHNOLOGY & BIOTECHNOLOGY, Issue 8 2009
Pengcheng Fu
Abstract BACKGROUND: DNA microarrays technology has been used to obtain expression profiles of thousands of genes at the same time for a given organism at relatively low costs. While gene expression approaches are being developed which allow holistic analysis of complex biological processes, there exist very few illustrative examples on the integration of large scale modeling and high throughput time course experiments to upgrade the information contents on yeast biology. RESULTS:Saccharomyces cerevisiae cell culture experiments with perturbed growth conditions were designed so that the metabolic states would be shifted from one to another. Microarrays were used to explore changes in gene expression across the entire yeast genome during the perturbation experiments. Changes in transcript abundance in these growth periods were investigated to study the cellular response to different glucose and oxygen supply. Computational results and experimental observations representing the three characteristic metabolic states were compared on the S. cerevisiae metabolic pathways, as well as the visualization platform provided by the metabolic phenotypic phase plane (PhPP) for the gene regulation on cell metabolism and adaptation of cells to environmental changes. CONCLUSIONS: The integrated expression study described reveals that S. cerevisiae cells respond to environmental changes mainly by down-regulating a number of genes to alter the cell metabolism so that the cells adapt to the variations in their growth conditions. Copyright © 2009 Society of Chemical Industry [source]

The Arabidopsis thaliana ATP-binding cassette proteins: an emerging superfamily

PLANT CELL & ENVIRONMENT, Issue 5 2000
T. G. E. Davies
ABSTRACT Solute transport systems are one of the major ways in which organisms interact with their environment. Typically, transport is catalysed by integral membrane proteins, of which one of the largest groups is the ATP-binding cassette (ABC) proteins. On the basis of sequence similarities, a large family of ABC proteins has been identified in Arabidopsis. A total of 60 open reading frames (ORFs) encoding ABC proteins were identified by BLAST homology searching of the nuclear genome. These 60 putative proteins include 89 ABC domains. Based on the assignment of transmembrane domains (TMDs), at least 49 of the 60 proteins identified are ABC transporters. Of these 49 proteins, 28 are full-length ABC transporters (eight of which have been described previously), and 21 are uncharacterized half-transporters. Three of the remaining proteins identified appear to be soluble, lacking identifiable TMDs, and most likely have non-transport functions. The eight other ORFs have homology to the nucleotide-binding and transmembrane components of multi-subunit permeases. The majority of ABC proteins found in Arabidopsis can, on the basis of sequence homology, be assigned to subfamilies equivalent to those found in the yeast genome. This assignment of the Arabidopsis ABC proteins into easily recognizable subfamilies (with distinguishable subclusters) is an important first step in the elucidation of their functional role in higher plants. [source]

Nonparametric Inference for Local Extrema with Application to Oligonucleotide Microarray Data in Yeast Genome

BIOMETRICS, Issue 2 2006
Peter X.-K.
Summary Identifying local extrema of expression profiles is one primary objective in some cDNA microarray experiments. To study the replication dynamics of the yeast genome, for example, local peaks of hybridization intensity profiles correspond to putative replication origins. We propose a nonparametric kernel smoothing (NKS) technique to detect local hybridization intensity extrema across chromosomes. The novelty of our approach is that we base our inference procedures on equilibrium points, namely those locations at which the first derivative of the intensity curve is zero. The proposed smoothing technique provides both point and interval estimation for the location of local extrema. Also, this technique can be used to test for the hypothesis of either one or multiple suspected locations being the true equilibrium points. We illustrate the proposed method on a microarray data set from an experiment designed to study the replication origins in the yeast genome, in that the locations of autonomous replication sequence (ARS) elements are identified through the equilibrium points of the smoothed intensity profile curve. Our method found a few ARS elements that were not detected by the current smoothing methods such as the Fourier convolution smoothing. [source]