Your search keyword '"Marker selection"' showing total 137 results

1. Multivariate Adaptive Regression Splines Enhance Genomic Prediction of Non-Additive Traits.

Author

de Oliveira Celeri, Maurício, da Costa, Weverton Gomes, Nascimento, Ana Carolina Campana, Azevedo, Camila Ferreira, Cruz, Cosme Damião, Sagae, Vitor Seiti, and Nascimento, Moysés

Subjects

*LINKAGE disequilibrium, *LOCUS of control, *PREDICTION models, *HERITABILITY, *LOCUS (Genetics)

Abstract

The present work used Multivariate Adaptive Regression Splines (MARS) for genomic prediction and to study the non-additive fraction present in a trait. To this end, 12 scenarios for an F2 population were simulated by combining three levels of broad-sense heritability (h2 = 0.3, 0.5, and 0.8) and four amounts of QTLs controlling the trait (8, 40, 80, and 120). All scenarios included non-additive effects due to dominance and additive–additive epistasis. The individuals' genomic estimated breeding values (GEBV) were predicted via MARS and compared against the GBLUP method, whose models were additive, additive–dominant, and additive–epistatic. In addition, a linkage disequilibrium study between markers and QTL was performed. Linkage maps highlighted the QTL and molecular markers identified by the methodologies under study. MARS showed superior results to the GBLUP models regarding predictive ability for traits controlled by 8 loci, and results were similar for traits controlled by more than 40 loci. Moreover, the use of MARS, together with a linkage disequilibrium study of the trait, can help to elucidate the traits' genetic architecture. Therefore, MARS showed potential to improve genomic prediction, especially for oligogenic traits or traits controlled by approximately 40 QTLs, while enabling the elucidation of the genetic architecture of traits. [ABSTRACT FROM AUTHOR]

Published

2024

2. Refining the optimal CAF cluster marker for predicting TME-dependent survival expectancy and treatment benefits in NSCLC patients

Author

Kai Li, Rui Wang, Guo-Wei Liu, Zi-Yang Peng, Ji-Chang Wang, Guo-Dong Xiao, Shou-Ching Tang, Ning Du, Jia Zhang, Jing Zhang, Hong Ren, Xin Sun, Yi-Ping Yang, and Da-Peng Liu

Subjects

Tumor microenvironment, Cancer associated fibroblasts, scRNA sequence data, Marker selection, Therapy response, Medicine, Science

Abstract

Abstract The tumor microenvironment (TME) plays a pivotal role in the onset, progression, and treatment response of cancer. Among the various components of the TME, cancer-associated fibroblasts (CAFs) are key regulators of both immune and non-immune cellular functions. Leveraging single-cell RNA sequencing (scRNA) data, we have uncovered previously hidden and promising roles within this specific CAF subgroup, paving the way for its clinical application. However, several critical questions persist, primarily stemming from the heterogeneous nature of CAFs and the use of different fibroblast markers in various sample analyses, causing confusion and hindrance in their clinical implementation. In this groundbreaking study, we have systematically screened multiple databases to identify the most robust marker for distinguishing CAFs in lung cancer, with a particular focus on their potential use in early diagnosis, staging, and treatment response evaluation. Our investigation revealed that COL1A1, COL1A2, FAP, and PDGFRA are effective markers for characterizing CAF subgroups in most lung adenocarcinoma datasets. Through comprehensive analysis of treatment responses, we determined that COL1A1 stands out as the most effective indicator among all CAF markers. COL1A1 not only deciphers the TME signatures related to CAFs but also demonstrates a highly sensitive and specific correlation with treatment responses and multiple survival outcomes. For the first time, we have unveiled the distinct roles played by clusters of CAF markers in differentiating various TME groups. Our findings confirm the sensitive and unique contributions of CAFs to the responses of multiple lung cancer therapies. These insights significantly enhance our understanding of TME functions and drive the translational application of extensive scRNA sequence results. COL1A1 emerges as the most sensitive and specific marker for defining CAF subgroups in scRNA analysis. The CAF ratios represented by COL1A1 can potentially serve as a reliable predictor of treatment responses in clinical practice, thus providing valuable insights into the influential roles of TME components. This research marks a crucial step forward in revolutionizing our approach to cancer diagnosis and treatment.

Published

2024

3. Refining the optimal CAF cluster marker for predicting TME-dependent survival expectancy and treatment benefits in NSCLC patients.

Author

Li, Kai, Wang, Rui, Liu, Guo-Wei, Peng, Zi-Yang, Wang, Ji-Chang, Xiao, Guo-Dong, Tang, Shou-Ching, Du, Ning, Zhang, Jia, Zhang, Jing, Ren, Hong, Sun, Xin, Yang, Yi-Ping, and Liu, Da-Peng

Subjects

*NON-small-cell lung carcinoma, *LUNGS, *CELL physiology, *RNA sequencing, *TUMOR microenvironment, *LIFE expectancy, *LUNG cancer

Abstract

The tumor microenvironment (TME) plays a pivotal role in the onset, progression, and treatment response of cancer. Among the various components of the TME, cancer-associated fibroblasts (CAFs) are key regulators of both immune and non-immune cellular functions. Leveraging single-cell RNA sequencing (scRNA) data, we have uncovered previously hidden and promising roles within this specific CAF subgroup, paving the way for its clinical application. However, several critical questions persist, primarily stemming from the heterogeneous nature of CAFs and the use of different fibroblast markers in various sample analyses, causing confusion and hindrance in their clinical implementation. In this groundbreaking study, we have systematically screened multiple databases to identify the most robust marker for distinguishing CAFs in lung cancer, with a particular focus on their potential use in early diagnosis, staging, and treatment response evaluation. Our investigation revealed that COL1A1, COL1A2, FAP, and PDGFRA are effective markers for characterizing CAF subgroups in most lung adenocarcinoma datasets. Through comprehensive analysis of treatment responses, we determined that COL1A1 stands out as the most effective indicator among all CAF markers. COL1A1 not only deciphers the TME signatures related to CAFs but also demonstrates a highly sensitive and specific correlation with treatment responses and multiple survival outcomes. For the first time, we have unveiled the distinct roles played by clusters of CAF markers in differentiating various TME groups. Our findings confirm the sensitive and unique contributions of CAFs to the responses of multiple lung cancer therapies. These insights significantly enhance our understanding of TME functions and drive the translational application of extensive scRNA sequence results. COL1A1 emerges as the most sensitive and specific marker for defining CAF subgroups in scRNA analysis. The CAF ratios represented by COL1A1 can potentially serve as a reliable predictor of treatment responses in clinical practice, thus providing valuable insights into the influential roles of TME components. This research marks a crucial step forward in revolutionizing our approach to cancer diagnosis and treatment. [ABSTRACT FROM AUTHOR]

Published

2024

4. Molecular and genetic basis of tomato resistance to major fungal diseases

Author

M. V. Maslova, I. N. Shamshin, E. V. Grosheva, and A. S. Ilyichev

Subjects

tomato, phytophthora infestans, fusarium oxysporum, cladosporium fulvum, alternaria, resistance genes, marker selection, Agriculture

Abstract

This review presents an analysis of the literature, which indicates the popularity of breeding methods in the fight against oomycete and fungal diseases of tomato: late blight (pathogen − Phytophthora infestans (Mont.) de Bary), fusarium wilt (pathogen − Fusarium oxysporum f. sp. lycopersici (Sacc.) Snyder and Hansen), early blight or alternariosis (pathogens − representatives of the genus Alternaria), cladosporiosis (pathogen−Cladosporium fulvum Cook.). Theoretical and practical achievements, the latest developments in genetics, molecular biology, plant physiology, microbiology are considered. Special attention is paid to modern information about the diversity of tomato pathogens, their morphological, genetic, physiological features, including racial composition; the presence of pathogen resistance genes in the gene pool of the culture under study, their mapping and the possibility of introduction into the genome from other sources; about the developed markers of target genes and loci of quantitative traits; the degree of associations between a molecular marker and a target gene; about the features of inheritance of the studied trait, as well as the possibility of pyramiding R-genes and QTL in one genotype. To accelerate and improve the efficiency of tomato breeding for resistance to pathogens, these issues are of great importance. Their study will strengthen the integration of modern biotechnology with the traditional breeding process, which is carried out by classical methods.

Published

2023

5. Multivariate Adaptive Regression Splines Enhance Genomic Prediction of Non-Additive Traits

Author

Maurício de Oliveira Celeri, Weverton Gomes da Costa, Ana Carolina Campana Nascimento, Camila Ferreira Azevedo, Cosme Damião Cruz, Vitor Seiti Sagae, and Moysés Nascimento

Subjects

dominance, epistasis, marker selection, oligogenic trait, Agriculture

Abstract

The present work used Multivariate Adaptive Regression Splines (MARS) for genomic prediction and to study the non-additive fraction present in a trait. To this end, 12 scenarios for an F2 population were simulated by combining three levels of broad-sense heritability (h2 = 0.3, 0.5, and 0.8) and four amounts of QTLs controlling the trait (8, 40, 80, and 120). All scenarios included non-additive effects due to dominance and additive–additive epistasis. The individuals’ genomic estimated breeding values (GEBV) were predicted via MARS and compared against the GBLUP method, whose models were additive, additive–dominant, and additive–epistatic. In addition, a linkage disequilibrium study between markers and QTL was performed. Linkage maps highlighted the QTL and molecular markers identified by the methodologies under study. MARS showed superior results to the GBLUP models regarding predictive ability for traits controlled by 8 loci, and results were similar for traits controlled by more than 40 loci. Moreover, the use of MARS, together with a linkage disequilibrium study of the trait, can help to elucidate the traits’ genetic architecture. Therefore, MARS showed potential to improve genomic prediction, especially for oligogenic traits or traits controlled by approximately 40 QTLs, while enabling the elucidation of the genetic architecture of traits.

Published

2024

6. Optimizing Microsatellite Marker Panels for Genetic Diversity and Population Genetic Studies: An Ant Colony Algorithm Approach with Polymorphic Information Content.

Author

Rasoarahona, Ryan, Wattanadilokchatkun, Pish, Panthum, Thitipong, Thong, Thanyapat, Singchat, Worapong, Ahmad, Syed Farhan, Chaiyes, Aingorn, Han, Kyudong, Kraichak, Ekaphan, Muangmai, Narongrit, Koga, Akihiko, Duengkae, Prateep, Antunes, Agostinho, and Srikulnath, Kornsorn

Subjects

*MICROSATELLITE repeats, *GENETIC variation, *ANT algorithms, *GENETIC markers, *OPTIMIZATION algorithms, *CHOICE (Psychology)

Abstract

Simple Summary: Microsatellite markers are widely used molecular markers for genetic studies, but choosing the right set involves a challenging trade-off between effectiveness and cost. The research aims to enhance the widely used ant colony optimization algorithm by integrating marker effectiveness indicators. By considering the genetic properties of the markers such as the polymorphic information content, the study seeks to determine the suitable way to select a reduced set of microsatellites. The approach addresses the accuracy–cost trade-off, aiding genetic assessments, breeding, and conservation efforts with cost-effective solutions. This research provides valuable insights into real-world genetic studies, including breeding programs and conservation initiatives. Microsatellites are polymorphic and cost-effective. Optimizing reduced microsatellite panels using heuristic algorithms eases budget constraints in genetic diversity and population genetic assessments. Microsatellite marker efficiency is strongly associated with its polymorphism and is quantified as the polymorphic information content (PIC). Nevertheless, marker selection cannot rely solely on PIC. In this study, the ant colony optimization (ACO) algorithm, a widely recognized optimization method, was adopted to create an enhanced selection scheme for refining microsatellite marker panels, called the PIC–ACO selection scheme. The algorithm was fine-tuned and validated using extensive datasets of chicken (Gallus gallus) and Chinese gorals (Naemorhedus griseus) from our previous studies. In contrast to basic optimization algorithms that stochastically initialize potential outputs, our selection algorithm utilizes the PIC values of markers to prime the ACO process. This increases the global solution discovery speed while reducing the likelihood of becoming trapped in local solutions. This process facilitated the acquisition of a cost-efficient and optimized microsatellite marker panel for studying genetic diversity and population genetic datasets. The established microsatellite efficiency metrics such as PIC, allele richness, and heterozygosity were correlated with the actual effectiveness of the microsatellite marker panel. This approach could substantially reduce budgetary barriers to population genetic assessments, breeding, and conservation programs. [ABSTRACT FROM AUTHOR]

Published

2023

7. Stable isotope and trace element analyses with non‐linear machine‐learning data analysis improved coffee origin classification and marker selection.

Author

Sim, Joy, Mcgoverin, Cushla, Oey, Indrawati, Frew, Russell, and Kebede, Biniam

Subjects

*TRACE element analysis, *STABLE isotopes, *MACHINE learning, *NONLINEAR analysis, *DATA analysis, *COFFEE beans, *TRACE elements

Abstract

BACKGROUND: This study investigated the geographical origin classification of green coffee beans from continental to country and regional levels. An innovative approach combined stable isotope and trace element analyses with non‐linear machine learning data analysis to improve coffee origin classification and marker selection. Specialty green coffee beans sourced from three continents, eight countries, and 22 regions were analyzed by measuring five isotope ratios (δ13C, δ15N, δ18O, δ2H, and δ34S) and 41 trace elements. Partial least squares discriminant analysis (PLS‐DA) was applied to the integrated dataset for origin classification. RESULTS: Origins were predicted well at the country level and showed promise at the regional level, with discriminating marker selection at all levels. However, PLS‐DA predicted origin poorly at the continental and Central American regional levels. Non‐linear machine learning techniques improved predictions and enabled the identification of a higher number of origin markers, and those that were identified were more relevant. The best predictive accuracy was found using ensemble decision trees, random forest and extreme gradient boost, with accuracies of up to 0.94 and 0.89 for continental and Central American regional models, respectively. CONCLUSION: The potential for advanced machine learning models to improve origin classification and the identification of relevant origin markers was demonstrated. The decision‐tree‐based models were superior with their embedded variable identification features and visual interpretation. © 2023 The Authors. Journal of The Science of Food and Agriculture published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2023

8. ImputAccur: fast and user-friendly calculation of genotype-imputation accuracy-measures

Author

Kolja A. Thormann, Viola Tozzi, Paula Starke, Heike Bickeböller, Marcus Baum, and Albert Rosenberger

Subjects

Imputation, Accuracy, GWAS, Marker selection, SNP, Quality control, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background ImputAccur is a software tool to measure genotype-imputation accuracy. Imputation of untyped markers is a standard approach in genome-wide association studies to close the gap between directly genotyped and other known DNA variants. However, high accuracy for imputed genotypes is fundamental. Several accuracy measures have been proposed, but unfortunately, they are implemented on different platforms, which is impractical. Results With ImputAccur, the accuracy measures info, Iam-hiQ and r 2 -based indices can be derived from standard output files of imputation software. Sample/probe and marker filtering is possible. This allows e.g. accurate marker filtering ahead of data analysis. Conclusions The source code (Python version 3.9.4), a standalone executive file, and example data for ImputAccur are freely available at https://gitlab.gwdg.de/kolja.thormann1/imputationquality.git .

Published

2022

9. A Multimodal Omics Exploration of the Motor and Non-Motor Symptoms of Parkinson’s Disease

Author

François-Xavier Lejeune, Farid Ichou, Etienne Camenen, Benoit Colsch, Florence Mauger, Caroline Peltier, Ivan Moszer, Emmanuel Gilson, Morgane Pierre-Jean, Edith Le Floch, Victor Sabarly, Arthur Tenenhaus, Jean-François Deleuze, Claire Ewenczyk, Marie Vidailhet, and Fanny Mochel

Subjects

Parkinson’s disease, multi-omics, data integration, marker selection, lipidomics, transcriptomics, Computer applications to medicine. Medical informatics, R858-859.7

Abstract

Parkinson’s disease (PD) is the second most common neurodegenerative disease clinically characterized by classical motor symptoms and a range of associated non-motor symptoms. Due to the heterogeneity of symptoms and variability in patient prognosis, the discovery of blood biomarkers is of utmost importance to identify the biological mechanisms underlying the different clinical manifestations of PD, monitor its progression and develop personalized treatment strategies. Whereas studies often rely on motor symptoms alone or composite scores, our study focused on finding relevant molecular markers associated with three clinical models describing either motor, cognitive or emotional symptoms. An integrative multiblock approach was performed using regularized generalized canonical correlation analysis to determine specific associations between lipidomics, transcriptomics and clinical data in 48 PD patients. We identified omics signatures confirming that clinical manifestations of PD in our cohort could be classified according to motor, cognition or emotion models. We found that immune-related genes and triglycerides were well-correlated with motor variables, while cognitive variables were linked to triglycerides as well as genes involved in neuronal growth, synaptic plasticity and mitochondrial fatty acid oxidation. Furthermore, emotion variables were associated with phosphatidylcholines, cholesteryl esters and genes related to endoplasmic reticulum stress and cell regulation.

Published

2022

10. Optimizing Microsatellite Marker Panels for Genetic Diversity and Population Genetic Studies: An Ant Colony Algorithm Approach with Polymorphic Information Content

Author

Ryan Rasoarahona, Pish Wattanadilokchatkun, Thitipong Panthum, Thanyapat Thong, Worapong Singchat, Syed Farhan Ahmad, Aingorn Chaiyes, Kyudong Han, Ekaphan Kraichak, Narongrit Muangmai, Akihiko Koga, Prateep Duengkae, Agostinho Antunes, and Kornsorn Srikulnath

Subjects

ant colony optimization, microsatellite, marker selection, polymorphic information, population genetics, Biology (General), QH301-705.5

Abstract

Microsatellites are polymorphic and cost-effective. Optimizing reduced microsatellite panels using heuristic algorithms eases budget constraints in genetic diversity and population genetic assessments. Microsatellite marker efficiency is strongly associated with its polymorphism and is quantified as the polymorphic information content (PIC). Nevertheless, marker selection cannot rely solely on PIC. In this study, the ant colony optimization (ACO) algorithm, a widely recognized optimization method, was adopted to create an enhanced selection scheme for refining microsatellite marker panels, called the PIC–ACO selection scheme. The algorithm was fine-tuned and validated using extensive datasets of chicken (Gallus gallus) and Chinese gorals (Naemorhedus griseus) from our previous studies. In contrast to basic optimization algorithms that stochastically initialize potential outputs, our selection algorithm utilizes the PIC values of markers to prime the ACO process. This increases the global solution discovery speed while reducing the likelihood of becoming trapped in local solutions. This process facilitated the acquisition of a cost-efficient and optimized microsatellite marker panel for studying genetic diversity and population genetic datasets. The established microsatellite efficiency metrics such as PIC, allele richness, and heterozygosity were correlated with the actual effectiveness of the microsatellite marker panel. This approach could substantially reduce budgetary barriers to population genetic assessments, breeding, and conservation programs.

Published

2023

11. ImputAccur: fast and user-friendly calculation of genotype-imputation accuracy-measures.

Author

Thormann, Kolja A., Tozzi, Viola, Starke, Paula, Bickeböller, Heike, Baum, Marcus, and Rosenberger, Albert

Subjects

*GENOME-wide association studies, *PYTHON programming language, *SOURCE code, *PRODUCTION standards, *SOFTWARE development tools

Abstract

Background: ImputAccur is a software tool to measure genotype-imputation accuracy. Imputation of untyped markers is a standard approach in genome-wide association studies to close the gap between directly genotyped and other known DNA variants. However, high accuracy for imputed genotypes is fundamental. Several accuracy measures have been proposed, but unfortunately, they are implemented on different platforms, which is impractical. Results: With ImputAccur, the accuracy measures info, Iam-hiQ and r2-based indices can be derived from standard output files of imputation software. Sample/probe and marker filtering is possible. This allows e.g. accurate marker filtering ahead of data analysis. Conclusions: The source code (Python version 3.9.4), a standalone executive file, and example data for ImputAccur are freely available at https://gitlab.gwdg.de/kolja.thormann1/imputationquality.git. [ABSTRACT FROM AUTHOR]

Published

2022

12. Risk prediction and marker selection in nonsynonymous single nucleotide polymorphisms using whole genome sequencing data

Author

Young-Sup Lee, KyeongHye Won, Donghyun Shin, and Jae-Don Oh

Subjects

breeding, deleterious effect, marker selection, nssnp, risk prediction, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Despite the various existing studies about nonsynonymous single nucleotide polymorphisms (nsSNPs), genome-wide studies based on nsSNPs are rare. NsSNPs alter amino acid sequences, affect protein structure and function, and have deleterious effects. By predicting the deleterious effect of nsSNPs, we determined the total risk score per individual. Additionally, the machine learning technique was utilized to find an optimal nsSNP subset that best explains the complete nsSNP effect. A total of 16,100 nsSNPs were selected as the best representatives among 89,519 regressed nsSNPs. In the gene ontology analysis encompassing the 16,100 nsSNPs, DNA metabolic process, chemokine- and immune-related, and reproduction were the most enriched terms. We expect that our risk score prediction and nsSNP marker selection will contribute to future development of extant genome-wide association studies and breeding science more broadly.

Published

2020

13. Russet Potato Breeding Clones with Extreme Resistance to Potato Virus Y Conferred by Rychc as well as Resistance to Late Blight and Cold-Induced Sweetening.

Author

Elison, Gregory L., Novy, Richard G., and Whitworth, Jonathan L.

Subjects

*POTATO virus Y, *POTATOES, *TUBERS, *PLANT clones, *VIRUS diseases

Abstract

Potato virus Y (PVY) impacts potato production worldwide by reducing potato yield, tuber quality, and successful certification of seed. Extreme resistance to PVY is conferred by three genes (Ryadg, Rysto, and Rychc) which have been introgressed from wild species into cultivated varieties. Both Rysto and Ryadg are used in many breeding programs worldwide, but Rychc is found in only a limited number of varieties and previously had been absent in varieties and germplasm representative of the russet market class that is widely grown in North America. Five russet breeding clones were identified as having the molecular marker associated with Rychc. Confirmation of the presence of Rychc was established following field and greenhouse screening of the clones for resistance to PVY with no infection by the virus being observed. These clones also have been characterized as having resistance to late blight and cold-induced sweetening of tubers and all are male-fertile as well. The unique assemblage of resistances in this russet germplasm will be of value to the potato breeding community in the development of russet potato varieties, especially with respect to Rychc which previously has not been reported as being present in this potato market class. [ABSTRACT FROM AUTHOR]

Published

2021

14. A rank-based marker selection method for high throughput scRNA-seq data

Author

Alexander H. S. Vargo and Anna C. Gilbert

Subjects

Single cell RNA-seq, Marker selection, Machine learning, Data analysis, Algorithms, Benchmarking, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background High throughput microfluidic protocols in single cell RNA sequencing (scRNA-seq) collect mRNA counts from up to one million individual cells in a single experiment; this enables high resolution studies of rare cell types and cell development pathways. Determining small sets of genetic markers that can identify specific cell populations is thus one of the major objectives of computational analysis of mRNA counts data. Many tools have been developed for marker selection on single cell data; most of them, however, are based on complex statistical models and handle the multi-class case in an ad-hoc manner. Results We introduce RankCorr, a fast method with strong mathematical underpinnings that performs multi-class marker selection in an informed manner. RankCorr proceeds by ranking the mRNA counts data before linearly separating the ranked data using a small number of genes. The step of ranking is intuitively natural for scRNA-seq data and provides a non-parametric method for analyzing count data. In addition, we present several performance measures for evaluating the quality of a set of markers when there is no known ground truth. Using these metrics, we compare the performance of RankCorr to a variety of other marker selection methods on an assortment of experimental and synthetic data sets that range in size from several thousand to one million cells. Conclusions According to the metrics introduced in this work, RankCorr is consistently one of most optimal marker selection methods on scRNA-seq data. Most methods show similar overall performance, however; thus, the speed of the algorithm is the most important consideration for large data sets (and comparing the markers selected by several methods can be fruitful). RankCorr is fast enough to easily handle the largest data sets and, as such, it is a useful tool to add into computational pipelines when dealing with high throughput scRNA-seq data. RankCorr software is available for download at https://github.com/ahsv/RankCorr with extensive documentation.

Published

2020

15. Efficiency of using SNP markers in the MSTN gene in the selection of the Pushkin breed chickens

Author

N. V. Dementeva, A. B. Vakhrameev, T. A. Larkina, and O. V. Mitrofanova

Subjects

pcr-rflp, polymorphism, myostatin, chickens, marker selection, exterior, Genetics, QH426-470

Abstract

In the poultry industry, indicators reflecting the growth rate of young stock and the exterior characteristics of chickens are important benchmarks for breeding. Traditional selection based on phenotypic evaluation is characterized by low efficiency with a low character inheritance ratio and is difficult to apply in small groups of animals and birds bred in bioresource collections. The use of molecular genetic markers associated with economically important traits makes it possible to carry out early selection of birds. This entails an increase in the profitability of the poultry industry. Recently, single nucleotide polymorphisms (SNPs) have served as convenient markers for selection purposes. For five generations (P1–P5), an experimental selection of hens of the Pushkin breed was carried out for live weight. It was based on selection for single nucleotide polymorphism rs313744840 in the MSTN gene. As a result, a significant increase in the frequency of allele A in this gene, from 0.11 to 0.50, took place. The association of SNP markers with meat qualities in the experimental group led to changes in the exterior profile of an adult bird at 330 days of age. The individuals with the AA and AG genotypes had the greatest live weight and longest body. As a result of selection, the bird on average became larger due to an increase in the number of heterozygous individuals with long bodies and large chest girths. The depth of the chest and the width of the pelvis increased due to an increase in the frequency of allele A in the experimental population. A tendency towards an increase in these indicators with the substitution of G with A in the genotype was found. Saturation of the population with desirable alleles led to an increase in the average live weight of the chickens. Analysis of the exterior parameters of adult birds showed that this growth is achieved by increasing the depth and volume of the bird body, and not by increasing the length of the limbs. Thus, marker selection carried out for five generations in the experimental population of Pushkin breed chickens to increase body weight has reliably (p < 0.001) changed the exterior profile of adult birds.

Published

2020

16. Development of polymorphic markers in the immune gene complex loci of cattle.

Author

Bakshy, K., Heimeier, D., Schwartz, J.C., Glass, E.J., Wilkinson, S., Skuce, R.A., Allen, A.R., Young, J., McClure, J.C., Cole, J.B., Null, D.J., Hammond, J.A., Smith, T.P.L., and Bickhart, D.M.

Subjects

*BIOMARKERS, *SHOTGUN sequencing, *BACTERIAL artificial chromosomes, *IMMUNE complexes, *HEALTH of cattle, *KILLER cells

Abstract

The addition of cattle health and immunity traits to genomic selection indices holds promise to increase individual animal longevity and productivity, and decrease economic losses from disease. However, highly variable genomic loci that contain multiple immune-related genes were poorly assembled in the first iterations of the cattle reference genome assembly and underrepresented during the development of most commercial genotyping platforms. As a consequence, there is a paucity of genetic markers within these loci that may track haplotypes related to disease susceptibility. By using hierarchical assembly of bacterial artificial chromosome inserts spanning 3 of these immune-related gene regions, we were able to assemble multiple full-length haplotypes of the major histocompatibility complex, the leukocyte receptor complex, and the natural killer cell complex. Using these new assemblies and the recently released ARS-UCD1.2 reference, we aligned whole-genome shotgun reads from 125 sequenced Holstein bulls to discover candidate variants for genetic marker development. We selected 124 SNPs, using heuristic and statistical models to develop a custom genotyping panel. In a proof-of-principle study, we used this custom panel to genotype 1,797 Holstein cows exposed to bovine tuberculosis (bTB) that were the subject of a previous GWAS study using the Illumina BovineHD array. Although we did not identify any significant association of bTB phenotypes with these new genetic markers, 2 markers exhibited substantial effects on bTB phenotypic prediction. The models and parameters trained in this study serve as a guide for future marker discovery surveys particularly in previously unassembled regions of the cattle genome. [ABSTRACT FROM AUTHOR]

Published

2021

17. Marker selection and genomic prediction of economically important traits using imputed high-density genotypes for 5 breeds of dairy cattle.

Author

Al-Khudhair, A., VanRaden, P.M., Null, D.J., and Li, B.

Subjects

*CATTLE breeds, *DAIRY cattle, *CATTLE breeding, *PHENOTYPES, *GENETIC markers, *ANIMAL young, *GENOTYPES

Abstract

Marker sets used in US dairy genomic predictions were previously expanded by including high-density (HD) or sequence markers with the largest effects for Holstein breed only. Other non-Holstein breeds lacked enough HD genotyped animals to be used as a reference population at that time, and thus were not included in the genomic prediction. Recently, numbers of non-Holstein breeds genotyped using HD panels reached an acceptable level for imputation and marker selection, allowing HD genomic prediction and HD marker selection for Holstein plus 4 other breeds. Genotypes for 351,461 Holsteins, 347,570 Jerseys, 42,346 Brown Swiss, 9,364 Ayrshires (including Red dairy cattle), and 4,599 Guernseys were imputed to the HD marker list that included 643,059 SNP. The separate HD reference populations included Illumina BovineHD (San Diego, CA) genotypes for 4,012 Holsteins, 407 Jerseys, 181 Brown Swiss, 527 Ayrshires, and 147 Guernseys. The 643,059 variants included the HD SNP and all 79,254 (80K) genetic markers and QTL used in routine national genomic evaluations. Before imputation, approximately 91 to 97% of genotypes were unknown for each breed; after imputation, 1.1% of Holstein, 3.2% of Jersey, 6.7% of Brown Swiss, 4.8% of Ayrshire, and 4.2% of Guernsey alleles remained unknown due to lower density haplotypes that had no matching HD haplotype. The higher remaining missing rates in non-Holstein breeds are mainly due to fewer HD genotyped animals in the imputation reference populations. Allele effects for up to 39 traits were estimated separately within each breed using phenotypic reference populations that included up to 6,157 Jersey males and 110,130 Jersey females. Correlations of HD with 80K genomic predictions for young animals averaged 0.986, 0.989, 0.985, 0.992, and 0.978 for Jersey, Ayrshire, Brown Swiss, Guernsey, and Holstein breeds, respectively. Correlations were highest for yield traits (about 0.991) and lowest for foot angle and rear legs–side view (0.981and 0.982, respectively). Some HD effects were more than twice as large as the largest 80K SNP effect, and HD markers had larger effects than nearby 80K markers for many breed-trait combinations. Previous studies selected and included markers with large effects for Holstein traits; the newly selected HD markers should also improve non-Holstein and crossbred genomic predictions and were added to official US genomic predictions in April 2020. [ABSTRACT FROM AUTHOR]

Published

2021

18. Risk prediction and marker selection in nonsynonymous single nucleotide polymorphisms using whole genome sequencing data.

Author

Lee, Young-Sup, Won, KyeongHye, Shin, Donghyun, and Oh, Jae-Don

Subjects

*SINGLE nucleotide polymorphisms, *NUCLEOTIDE sequencing, *AMINO acid sequence, *PROTEIN structure, *GENETIC markers in plants, *GENE ontology, *MACHINE learning

Abstract

Despite the various existing studies about nonsynonymous single nucleotide polymorphisms (nsSNPs), genome-wide studies based on nsSNPs are rare. NsSNPs alter amino acid sequences, affect protein structure and function, and have deleterious effects. By predicting the deleterious effect of nsSNPs, we determined the total risk score per individual. Additionally, the machine learning technique was utilized to find an optimal nsSNP subset that best explains the complete nsSNP effect. A total of 16,100 nsSNPs were selected as the best representatives among 89,519 regressed nsSNPs. In the gene ontology analysis encompassing the 16,100 nsSNPs, DNA metabolic process, chemokine- and immune-related, and reproduction were the most enriched terms. We expect that our risk score prediction and nsSNP marker selection will contribute to future development of extant genome-wide association studies and breeding science more broadly. [ABSTRACT FROM AUTHOR]

Published

2020

19. Best serum biomarker combination for ovarian cancer classification

Author

Hye-Jeong Song, Eun-Suk Yang, Jong-Dae Kim, Chan-Young Park, Min-Sun Kyung, and Yu-Seop Kim

Subjects

Marker selection, Classification, Ovarian cancer, Logistic regression, CA-125, Medical technology, R855-855.5

Abstract

Abstract Background Screening test using CA-125 is the most common test for detecting ovarian cancer. However, the level of CA-125 is diverse by variable condition other than ovarian cancer. It has led to misdiagnosis of ovarian cancer. Methods In this paper, we explore the 16 serum biomarker for finding alternative biomarker combination to reduce misdiagnosis. For experiment, we use the serum samples that contain 101 cancer and 92 healthy samples. We perform two major tasks: Marker selection and Classification. For optimal marker selection, we use genetic algorithm, random forest, T-test and logistic regression. For classification, we compare linear discriminative analysis, K-nearest neighbor and logistic regression. Results The final results show that the logistic regression gives high performance for both tasks, and HE4-ELISA, PDGF-AA, Prolactin, TTR is the best biomarker combination for detecting ovarian cancer. Conclusions We find the combination which contains TTR and Prolactin gives high performance for cancer detection. Early detection of ovarian cancer can reduce high mortality rates. Finding a combination of multiple biomarkers for diagnostic tests with high sensitivity and specificity is very important.

Published

2018

20. Optimizing Phylogenomics with Rapidly Evolving Long Exons: Comparison with Anchored Hybrid Enrichment and Ultraconserved Elements.

Author

Karin, Benjamin R, Gamble, Tony, and Jackman, Todd R

Abstract

Marker selection has emerged as an important component of phylogenomic study design due to rising concerns of the effects of gene tree estimation error, model misspecification, and data-type differences. Researchers must balance various trade-offs associated with locus length and evolutionary rate among other factors. The most commonly used reduced representation data sets for phylogenomics are ultraconserved elements (UCEs) and Anchored Hybrid Enrichment (AHE). Here, we introduce Rapidly Evolving Long Exon Capture (RELEC), a new set of loci that targets single exons that are both rapidly evolving (evolutionary rate faster than RAG1) and relatively long in length (>1,500 bp), while at the same time avoiding paralogy issues across amniotes. We compare the RELEC data set to UCEs and AHE in squamate reptiles by aligning and analyzing orthologous sequences from 17 squamate genomes, composed of 10 snakes and 7 lizards. The RELEC data set (179 loci) outperforms AHE and UCEs by maximizing per-locus genetic variation while maintaining presence and orthology across a range of evolutionary scales. RELEC markers show higher phylogenetic informativeness than UCE and AHE loci, and RELEC gene trees show greater similarity to the species tree than AHE or UCE gene trees. Furthermore, with fewer loci, RELEC remains computationally tractable for full Bayesian coalescent species tree analyses. We contrast RELEC to and discuss important aspects of comparable methods, and demonstrate how RELEC may be the most effective set of loci for resolving difficult nodes and rapid radiations. We provide several resources for capturing or extracting RELEC loci from other amniote groups. [ABSTRACT FROM AUTHOR]

Published

2020

21. Russet Potato Breeding Clones with Extreme Resistance to Potato Virus Y Conferred by Rychc as well as Resistance to Late Blight and Cold-Induced Sweetening

Author

Elison, Gregory L., Novy, Richard G., and Whitworth, Jonathan L.

Published

2021

22. NEW GENETIC SOURCES OF CYTOPLASMIC MALE STERILITY OF ONIONS (Allium cepa L.)

Author

A. N. Logunov, M. V. Budylin, and E. A. Tiko

Subjects

onion (allium cepa l.), cytoplasmic male sterility, genes of sterility fixers, molecular markers, marker selection, hybprob, real time pcr, Agriculture

Abstract

Actual problem in breeding onion (Allium cepa. L) is the identification of cytoplasm type in varieties and F1 hybrids. To create a parent sterile fixing line, is required a cytoplasm of type N. However, heterozygous F1 hybrids and new onion varieties obtained from subsequent generations from F1 fertility hybrids that possess economically valuable traits and meet market requirements are not suitable for creating a sterile fixing line from them, because all hybrid plants has 100% S-cytoplasm or T-cytoplasm type. In order to determine the most desirable parent component with subsequent use in the selection process, the Laboratory of Selection and Seed Production of Onion Cultures of the Gavrish company conducted a phenotypic and molecular analysis of collection samples of onions for the feature of male sterility. The material for research was grown according to the generally accepted technologies for the zone in the city of Krymsk, Krasnodar Territory. Phenotypic analysis of the manifestation of the "male sterility" feature was carried out with the help of visual analysis. As a result of the work, were identified varieties and F1 hybrids that can be used as genetic sources for the creation of new sterile lines and lines of sterility fixers, as well as samples to be used as pollinators. In the future, these lines will be used to create heterotic F1 hybrids with high indicators of economic characteristics with given properties.

Published

2018

23. Ottimizzazione delle risorse genetiche di una collezione privata di Capsicum spp. (Peperoni) attraverso approcci efficaci di pre-selezione

Author

Martelli, Marco

Subjects

miglioramento genico, peperone, selezione assistita, accumulo genico, geni di resistenza, gene pyramiding, pepper germplasm, resistance genes, plant breeding, Settore AGR/02 - Agronomia e Coltivazioni Erbacee, marker selection

Published

2023

24. Tournaments between markers as a strategy to enhance genomic predictions.

Author

Filho, Diógenes Ferreira, Filho, Júlio Sílvio de Sousa Bueno, Regitano, Luciana Correia de Almeida, Alencar, Maurício Mello de, Alves, Rosiana Rodrigues, and Meirelles, Sarah Laguna Conceição

Subjects

*TOURNAMENTS, *REGRESSION analysis, *MOLECULAR genetics, *BEEF cattle, *STATISTICS, *MULTICOLLINEARITY

Abstract

Analysis of a large number of markers is crucial in both genome-wide association studies (GWAS) and genome-wide selection (GWS). However there are two methodological issues that restrict statistical analysis: high dimensionality (p≫n) and multicollinearity. Although there are methodologies that can be used to fit models for data with high dimensionality (eg, the Bayesian Lasso), a big problem that can occurs in this cases is that the predictive ability of the model should perform well for the individuals used to fit the model, but should not perform well for other individuals, restricting the applicability of the model. This problem can be circumvent by applying some selection methodology to reduce the number of markers (but keeping the markers associated with the phenotypic trait) before adjusting a model to predict GBVs. We revisit a tournament-based strategy between marker samples, where each sample has good statistical properties for estimation: n>p and low collinearity. Such tournaments are elaborated using multiple linear regression to eliminate markers. This method is adapted from previous works found in the literature. We used simulated data as well as real data derived from a study with SNPs in beef cattle. Tournament strategies not only circumvent the p≫n issue, but also minimize spurious associations. For real data, when we selected a few more than 20 markers, we obtained correlations greater than 0.70 between predicted Genomic Breeding Values (GBVs) and phenotypes in validation groups of a cross-validation scheme; and when we selected a larger number of markers (more than 100), the correlations exceeded 0.90, showing the efficiency in identifying relevant SNPs (or segregations) for both GWAS and GWS. In the simulation study, we obtained similar results. [ABSTRACT FROM AUTHOR]

Published

2019

25. Selection of trait-specific markers and multi-environment models improve genomic predictive ability in rice.

Author

Bhandari, Aditi, Bartholomé, Jérôme, Cao-Hamadoun, Tuong-Vi, Kumari, Nilima, Frouin, Julien, Kumar, Arvind, and Ahmadi, Nourollah

Subjects

*BOTANY, *RICE varieties, *RICE, *COMPUTATIONAL biology, *DROUGHT tolerance, *DRY farming

Abstract

Developing high yielding rice varieties that are tolerant to drought stress is crucial for the sustainable livelihood of rice farmers in rainfed rice cropping ecosystems. Genomic selection (GS) promises to be an effective breeding option for these complex traits. We evaluated the effectiveness of two rather new options in the implementation of GS: trait and environment-specific marker selection and the use of multi-environment prediction models. A reference population of 280 rainfed lowland accessions endowed with 215k SNP markers data was phenotyped under a favorable and two managed drought environments. Trait-specific SNP subsets (28k) were selected for each trait under each environment, using results of GWAS performed with the complete genotype dataset. Performances of single-environment and multi-environment genomic prediction models were compared using kernel regression based methods (GBLUP and RKHS) under two cross validation scenarios: availability (CV2) or not (CV1) of phenotypic data for the validation set, in one of the environments. Trait-specific marker selection strategy achieved predictive ability (PA) of genomic prediction up to 22% higher than markers selected on the bases of neutral linkage disequilibrium (LD). Tolerance to drought stress was up to 32% better predicted by multi-environment models (especially RKHS based models) under CV2 strategy. Under the less favorable CV1 strategy, the multi-environment models achieved similar PA than the single-environment predictions. We also showed that reasonable PA could be obtained with as few as 3,000 SNP markers, even in a population of low LD extent, provided marker selection is based on pairwise LD. The implications of these findings for breeding for drought tolerance are discussed. The most resource sparing option would be accurate phenotyping of the reference population in a favorable environment and under a managed drought, while the candidate population would be phenotyped only under one of those environments. [ABSTRACT FROM AUTHOR]

Published

2019

26. Disease prediction by cell-free DNA methylation.

Author

Feng, Hao, Jin, Peng, and Wu, Hao

Subjects

*FORECASTING, *DNA methylation, *DATA analysis, *DIAGNOSIS, *PREDICTION models, *DNA

Abstract

Disease diagnosis using cell-free DNA (cfDNA) has been an active research field recently. Most existing approaches perform diagnosis based on the detection of sequence variants on cfDNA; thus, their applications are limited to diseases associated with high mutation rate such as cancer. Recent developments start to exploit the epigenetic information on cfDNA, which could have substantially wider applications. In this work, we provide thorough reviews and discussions on the statistical method developments and data analysis strategies for using cfDNA epigenetic profiles, in particular DNA methylation, to construct disease diagnostic models. We focus on two important aspects: marker selection and prediction model construction, under different scenarios. We perform simulations and real data analysis to compare different approaches, and provide recommendations for data analysis. [ABSTRACT FROM AUTHOR]

Published

2019

27. A Region-Based GeneSIS Segmentation Algorithm for the Classification of Remotely Sensed Images

Author

Stelios K. Mylonas, Dimitris G. Stavrakoudis, John B. Theocharis, and Paris A. Mastorocostas

Subjects

image segmentation, object-based classification, watershed transform, genetic algorithms, marker selection, segmentation fusion, Science

Abstract

This paper proposes an object-based segmentation/classification scheme for remotely sensed images, based on a novel variant of the recently proposed Genetic Sequential Image Segmentation (GeneSIS) algorithm. GeneSIS segments the image in an iterative manner, whereby at each iteration a single object is extracted via a genetic-based object extraction algorithm. Contrary to the previous pixel-based GeneSIS where the candidate objects to be extracted were evaluated through the fuzzy content of their included pixels, in the newly developed region-based GeneSIS algorithm, a watershed-driven fine segmentation map is initially obtained from the original image, which serves as the basis for the forthcoming GeneSIS segmentation. Furthermore, in order to enhance the spatial search capabilities, we introduce a more descriptive encoding scheme in the object extraction algorithm, where the structural search modules are represented by polygonal shapes. Our objectives in the new framework are posed as follows: enhance the flexibility of the algorithm in extracting more flexible object shapes, assure high level classification accuracies, and reduce the execution time of the segmentation, while at the same time preserving all the inherent attributes of the GeneSIS approach. Finally, exploiting the inherent attribute of GeneSIS to produce multiple segmentations, we also propose two segmentation fusion schemes that operate on the ensemble of segmentations generated by GeneSIS. Our approaches are tested on an urban and two agricultural images. The results show that region-based GeneSIS has considerably lower computational demands compared to the pixel-based one. Furthermore, the suggested methods achieve higher classification accuracies and good segmentation maps compared to a series of existing algorithms.

Published

2015

28. Identification of cancer omics commonality and difference via community fusion

Author

Yu Jiang, Yifan Sun, Shuangge Ma, and Yang Li

Subjects

Statistics and Probability, FOS: Computer and information sciences, Lung Neoplasms, Databases, Factual, Epidemiology, Computer science, Computational biology, 01 natural sciences, Statistics - Applications, Article, Omics data, Methodology (stat.ME), 010104 statistics & probability, 03 medical and health sciences, 0302 clinical medicine, Neoplasms, medicine, Humans, Applications (stat.AP), Quantitative Biology - Genomics, 030212 general & internal medicine, 0101 mathematics, Melanoma, Statistics - Methodology, Genomics (q-bio.GN), Single type, Cancer, Genomics, Omics, medicine.disease, FOS: Biological sciences, Regression Analysis, Identification (biology), Marker selection, Model building

Abstract

The analysis of cancer omics data is a "classic" problem, however, still remains challenging. Advancing from early studies that are mostly focused on a single type of cancer, some recent studies have analyzed data on multiple "related" cancer types/subtypes, examined their commonality and difference, and led to insightful findings. In this article, we consider the analysis of multiple omics datasets, with each dataset on one type/subtype of "related" cancers. A Community Fusion (CoFu) approach is developed, which conducts marker selection and model building using a novel penalization technique, informatively accommodates the network community structure of omics measurements, and automatically identifies the commonality and difference of cancer omics markers. Simulation demonstrates its superiority over direct competitors. The analysis of TCGA lung cancer and melanoma data leads to interesting findings, 33 pages, 11 figures

Published

2022

29. An integrative sparse boosting analysis of cancer genomic commonality and difference

Author

Yifan Sun, Zhengyang Sun, Yang Li, Shuangge Ma, and Yu Jiang

Subjects

FOS: Computer and information sciences, Statistics and Probability, Epidemiology, Computer science, Machine learning, computer.software_genre, 01 natural sciences, Statistics - Applications, Article, Methodology (stat.ME), 010104 statistics & probability, 03 medical and health sciences, Health Information Management, Neoplasms, Cancer genome, Covariate, Humans, Profiling (information science), Applications (stat.AP), Computer Simulation, Quantitative Biology - Genomics, 0101 mathematics, Statistics - Methodology, 030304 developmental biology, Genomics (q-bio.GN), 0303 health sciences, Multiple cancer, business.industry, Genomics, FOS: Biological sciences, Technical innovation, Data analysis, Artificial intelligence, business, Marker selection, computer

Abstract

In cancer research, high-throughput profiling has been extensively conducted. In recent studies, the integrative analysis of data on multiple cancer patient groups/subgroups has been conducted. Such analysis has the potential to reveal the genomic commonality as well as difference across groups/subgroups. However, in the existing literature, methods with a special attention to the genomic commonality and difference are very limited. In this study, a novel estimation and marker selection method based on the sparse boosting technique is developed to address the commonality/difference problem. In terms of technical innovation, a new penalty and computation of increments are introduced. The proposed method can also effectively accommodate the grouping structure of covariates. Simulation shows that it can outperform direct competitors under a wide spectrum of settings. The analysis of two TCGA (The Cancer Genome Atlas) datasets is conducted, showing that the proposed analysis can identify markers with important biological implications and have satisfactory prediction and stability., 13 pages

Published

2022

30. A set of 20 multiplexed single nucleotide polymorphism (SNP) markers specifically selected for the identification of the wild boar ( Sus scrofa scrofa) and the domestic pig ( Sus scrofa domesticus).

Author

Beugin, Marie-Pauline, Baubet, Eric, Dufaure De Citres, Caroline, Kaerle, Cécile, Muselet, Lina, Klein, François, and Queney, Guillaume

Abstract

In the last few decades, populations of wild boars have been spreading throughout Europe. This expansion is problematic because of conflicts with human activities and/or sanitary reasons. Thus, the need to develop tools to understand wild boar populations' increase as well as to manage efficiently their populations appears crucial but challenging. As ancestor of the domestic pig, one of the main issues associated with this population spread is the possible hybridization between the two subspecies which complicates the identification of pure individuals. In this study, we propose a set of 20 single nucleotide polymorphism (SNP) markers, allocated in two 10-plexes, selected in order to identify the two subspecies. The multiplexes were validated on reference populations of wild boars and domestic pigs in order to assess their polymorphism and their discriminative power. The selected markers allowed for an exacerbated differentiation between the wild boars and the domestic pigs compared to other studies and thus allows for an efficient identification of species. The low size of this panel of 20 SNP markers makes it a tool compatible with economic constraints associated with wildlife management compared to tools based on chips. [ABSTRACT FROM AUTHOR]

Published

2017

31. Introgression of LTP2 gene through marker assisted backcross in barley (Hordeum vulgare L.)

Author

Krzysztof Mikołajczak, Piotr Ogrodowicz, Maria Surma, Tadeusz Adamski, and Anetta Kuczyńska

Subjects

BC lines, Gene annotation, Semi-dwarf gene, Single nucleotide polymorphism spring barley, Marker selection, Marker-assisted backcrossing, Marker-assisted introgression, DNA markers, Selection in plant breeding, Biotechnology, TP248.13-248.65, Biology (General), QH301-705.5

Abstract

Background: Marker-assisted introgression currently represents the most widely spread application of DNA markers as an aid to selection in plant breeding. New barley germplasm should be supplemented by genes that facilitate growth and development under stressful conditions. The homology search against known genes is a fundamental approach to identify genes among the generated sequences. This procedure can be utilized for SNP search in genes of predicted function of interest and associated gene ontology (GO). Results: Backcross breeding enhanced by marker selection may become a powerful method to transfer one or a few genes controlling a specific trait. In the study, the integrated approach of combining phenotypic selection with marker assisted backcross breeding for introgression of LTP2 gene, in the background of semi-dwarf spring barley cultivar, was employed. This study discusses the efficiency of molecular marker application in backcrossing targeted on the selected gene. Conclusions: BC6 lines developed in this study can serve as a unique and adequate plant material to dissect the role of LTP2 gene. Due to its role in lipid transfer, the LTP2 may be crucial in lipidome modification in response to abiotic stress.

Published

2016

32. Optimum marker selection of acute liver damage in rats in the experiment

Author

E. S. Ustinova, I. M. Bykov, M I Bykov, I. Y. Tsymbalyuk, K A Popov, and R. I. Sepiashvili

Subjects

Pathology, medicine.medical_specialty, lcsh:R, lcsh:Medicine, General Medicine, ischemia, Biology, liver, reperfusion, cytolysis, medicine, hepatocytes, Liver damage, Marker selection

Abstract

Relevance. Assessment of liver damage and functional state is one of the leading tasks of clinical and laboratory diagnostics. Traditionally used methods for determining the activity of a number of indicator enzymes in blood with relative organ-specificity, such as aspartate aminotransferase, alanine aminotransferase, lactate dehydrogenase, sorbitol dehydrogenase, alkaline phosphatase, and -glutamyl transferase, have low specificity for liver diseases. In this regard, the determination of the optimal marker of acute liver injury is an urgent problem. Aim. The purpose of the study is to determine the dynamics of changes in liver damage markers in rats at different periods of reperfusion after 20 minutes of ischemia in order to select the indicators that most informatively characterize the state of test-animals under conditions of correction of ischemia-reperfusion syndrome. Materials and methods: the study was performed on 120 white nonlinear male rats weighing 200250 grams. The animals were divided into 8 groups of 15 test-animals; all of them were simulated liver ischemia by clamping the analog of the hepatoduodenal ligament with a vascular clamp for 20 minutes. Then, blood was taken from different groups of rats at different reperfusion times 5, 15, 30, 60, 120, 180 minutes, 8 hours and a day. In the blood plasma of laboratory animals, the activity of alanine aminotransferase (ALT), aspartate aminotransferase (AST), lactate dehydrogenase (LDH), glutathione transferase (GST), and lactate concentration were determined. Results: the results obtained allowed us to characterize two main peaks of indicators: a 5-minute period after restoration of blood flow the maximum activity of glutathione transferase and lactate concentration, increased by 3.94.7 times; 60180 minutes of reperfusion is the peak of aminotransferase activity, a significant increase in the activity of which begins 60 minutes after the restoration of blood flow and reaches its maximum by the 3rd hour of reperfusion, and LDH, the peak of which is recorded already by the 60th minute of revascularization. At the same time, after 8 hours of reperfusion, an obvious tendency for a decrease in all studied parameters was determined, which ends a day after modeling ischemia with a decrease to the level of control values. Conclusion: the assessment of organ damage in the ischemic period and the anti-ischemic effect of metabolic drugs can be carried out with the determination of an increase in lactate concentration and glutathione transferase activity almost immediately after restoration of blood flow. The development of injuries during the reperfusion period is more expedient to assess by determining AST, ALT and LDH after a 3-hour period of blood flow restoration, at which time the maximum values of markers are recorded under the condition of 20-minute total liver ischemia.

Published

2020

33. Risk prediction and marker selection in nonsynonymous single nucleotide polymorphisms using whole genome sequencing data

Author

Jae-Don Oh, Donghyun Shin, Kyeong-Hye Won, and Young-Sup Lee

Subjects

0301 basic medicine, Nonsynonymous substitution, Total risk, Single-nucleotide polymorphism, Computational biology, Biology, deleterious effect, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, risk prediction, 0302 clinical medicine, Extant taxon, nssnp, lcsh:QH301-705.5, Genetic association, marker selection, Whole genome sequencing, lcsh:R5-920, Gene ontology, Genes & Genomics, 030104 developmental biology, lcsh:Biology (General), 030220 oncology & carcinogenesis, breeding, Animal Science and Zoology, Marker selection, lcsh:Medicine (General), Research Article

Abstract

Despite the various existing studies about nonsynonymous single nucleotide polymorphisms (nsSNPs), genome-wide studies based on nsSNPs are rare. NsSNPs alter amino acid sequences, affect protein structure and function, and have deleterious effects. By predicting the deleterious effect of nsSNPs, we determined the total risk score per individual. Additionally, the machine learning technique was utilized to find an optimal nsSNP subset that best explains the complete nsSNP effect. A total of 16,100 nsSNPs were selected as the best representatives among 89,519 regressed nsSNPs. In the gene ontology analysis encompassing the 16,100 nsSNPs, DNA metabolic process, chemokine- and immune-related, and reproduction were the most enriched terms. We expect that our risk score prediction and nsSNP marker selection will contribute to future development of extant genome-wide association studies and breeding science more broadly.

Published

2020

34. A Multimodal Omics Exploration of the Motor and Non-Motor Symptoms of Parkinson’s Disease

Author

Mochel, François-Xavier Lejeune, Farid Ichou, Etienne Camenen, Benoit Colsch, Florence Mauger, Caroline Peltier, Ivan Moszer, Emmanuel Gilson, Morgane Pierre-Jean, Edith Le Floch, Victor Sabarly, Arthur Tenenhaus, Jean-François Deleuze, Claire Ewenczyk, Marie Vidailhet, and Fanny

Subjects

Parkinson’s disease, multi-omics, data integration, marker selection, lipidomics, transcriptomics

Abstract

Parkinson’s disease (PD) is the second most common neurodegenerative disease clinically characterized by classical motor symptoms and a range of associated non-motor symptoms. Due to the heterogeneity of symptoms and variability in patient prognosis, the discovery of blood biomarkers is of utmost importance to identify the biological mechanisms underlying the different clinical manifestations of PD, monitor its progression and develop personalized treatment strategies. Whereas studies often rely on motor symptoms alone or composite scores, our study focused on finding relevant molecular markers associated with three clinical models describing either motor, cognitive or emotional symptoms. An integrative multiblock approach was performed using regularized generalized canonical correlation analysis to determine specific associations between lipidomics, transcriptomics and clinical data in 48 PD patients. We identified omics signatures confirming that clinical manifestations of PD in our cohort could be classified according to motor, cognition or emotion models. We found that immune-related genes and triglycerides were well-correlated with motor variables, while cognitive variables were linked to triglycerides as well as genes involved in neuronal growth, synaptic plasticity and mitochondrial fatty acid oxidation. Furthermore, emotion variables were associated with phosphatidylcholines, cholesteryl esters and genes related to endoplasmic reticulum stress and cell regulation.

Published

2022

35. Multicompartment modeling of protein shedding kinetics during vascularized tumor growth

Author

Gautam B Machiraju, Parag Mallick, and Hermann B. Frieboes

Subjects

Multidisciplinary, Neovascularization, Pathologic, Extracellular proteins, Protein biomarkers, Mathematics and computing, Kinetics, lcsh:R, Cancer, lcsh:Medicine, Biology, medicine.disease, Models, Biological, Article, Cell biology, Tumour biomarkers, Neoplasms, Blood circulation, medicine, Humans, Tumor growth, lcsh:Q, Marker selection, lcsh:Science, Function (biology)

Abstract

Identification of protein biomarkers for cancer diagnosis and prognosis remains a critical unmet clinical need. A major reason is that the dynamic relationship between proliferating and necrotic cell populations during vascularized tumor growth, and the associated extra- and intra-cellular protein outflux from these populations into blood circulation remains poorly understood. Complementary to experimental efforts, mathematical approaches have been employed to effectively simulate the kinetics of detectable surface proteins (e.g., CA-125) shed into the bloodstream. However, existing models can be difficult to tune and may be unable to capture the dynamics of non-extracellular proteins, such as those shed from necrotic and apoptosing cells. The models may also fail to account for intra-tumoral spatial and microenvironmental heterogeneity. We present a new multi-compartment model to simulate heterogeneously vascularized growing tumors and the corresponding protein outflux. Model parameters can be tuned from histology data, including relative vascular volume, mean vessel diameter, and distance from vasculature to necrotic tissue. The model enables evaluating the difference in shedding rates between extra- and non-extracellular proteins from viable and necrosing cells as a function of heterogeneous vascularization. Simulation results indicate that under certain conditions it is possible for non-extracellular proteins to have superior outflux relative to extracellular proteins. This work contributes towards the goal of cancer biomarker identification by enabling simulation of protein shedding kinetics based on tumor tissue-specific characteristics. Ultimately, we anticipate that models like the one introduced herein will enable examining origins and circulating dynamics of candidate biomarkers, thus facilitating marker selection for validation studies.

Published

2020

36. A rank-based marker selection method for high throughput scRNA-seq data

Author

Anna C. Gilbert and Alexander Vargo

Subjects

Genetic Markers, Computer science, Data analysis, Bone Marrow Cells, computer.software_genre, lcsh:Computer applications to medicine. Medical informatics, Biochemistry, Set (abstract data type), Mice, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, Databases, Genetic, Machine learning, Animals, Cluster Analysis, Humans, Computer Simulation, Molecular Biology, Throughput (business), Gene, lcsh:QH301-705.5, 030304 developmental biology, 0303 health sciences, Base Sequence, Methodology Article, Gene Expression Profiling, Applied Mathematics, Rank (computer programming), High-Throughput Nucleotide Sequencing, Statistical model, Single cell RNA-seq, Computer Science Applications, Benchmarking, ROC Curve, Ranking, lcsh:Biology (General), Genetic marker, lcsh:R858-859.7, Data mining, Marker selection, Single-Cell Analysis, DNA microarray, computer, Software, 030217 neurology & neurosurgery, Algorithms, Count data

Abstract

Background High throughput microfluidic protocols in single cell RNA sequencing (scRNA-seq) collect mRNA counts from up to one million individual cells in a single experiment; this enables high resolution studies of rare cell types and cell development pathways. Determining small sets of genetic markers that can identify specific cell populations is thus one of the major objectives of computational analysis of mRNA counts data. Many tools have been developed for marker selection on single cell data; most of them, however, are based on complex statistical models and handle the multi-class case in an ad-hoc manner. Results We introduce RankCorr, a fast method with strong mathematical underpinnings that performs multi-class marker selection in an informed manner. RankCorr proceeds by ranking the mRNA counts data before linearly separating the ranked data using a small number of genes. The step of ranking is intuitively natural for scRNA-seq data and provides a non-parametric method for analyzing count data. In addition, we present several performance measures for evaluating the quality of a set of markers when there is no known ground truth. Using these metrics, we compare the performance of RankCorr to a variety of other marker selection methods on an assortment of experimental and synthetic data sets that range in size from several thousand to one million cells. Conclusions According to the metrics introduced in this work, RankCorr is consistently one of most optimal marker selection methods on scRNA-seq data. Most methods show similar overall performance, however; thus, the speed of the algorithm is the most important consideration for large data sets (and comparing the markers selected by several methods can be fruitful). RankCorr is fast enough to easily handle the largest data sets and, as such, it is a useful tool to add into computational pipelines when dealing with high throughput scRNA-seq data. RankCorr software is available for download at https://github.com/ahsv/RankCorrwith extensive documentation.

Published

2020

37. Biases in bulk: DNA metabarcoding of marine communities and the methodology involved

Author

Luna M. van der Loos and Reindert Nijland

Subjects

0106 biological sciences, 0301 basic medicine, PROTOCOL, SAMPLES, Touchdown polymerase chain reaction, Anthropogenic pressure, Biodiversity, DIVERSITY, BARCODE, 01 natural sciences, law.invention, DNA metabarcoding, chemistry.chemical_compound, law, Polymerase chain reaction, biodiversity, PCR CYCLE NUMBER, Ecology, Special Issue, marine monitoring, EXTRACTION METHODS, Marker selection, Ecological Genomics, Evolution, Computational biology, Biology, 010603 evolutionary biology, 03 medical and health sciences, Marine Animal Ecology, Behavior and Systematics, Bias, Systematics, Genetics, DNA Barcoding, Taxonomic, Marine ecosystem, BIODIVERSITY ASSESSMENT, PRESERVATION, Ecology, Evolution, Behavior and Systematics, Ecosystem, Behavior, SPECIES DETECTION, Biology and Life Sciences, Mariene Dierecologie, DNA, DNA extraction, MEIOFAUNA, METHODOLOGY AND COMPARISON WITH CONVENTIONAL METHODS, 030104 developmental biology, chemistry, Evolutionary biology, Earth and Environmental Sciences, WIAS, EPS, technical biases

Abstract

With the growing anthropogenic pressure on marine ecosystems, the need for efficient monitoring of biodiversity grows stronger. DNA metabarcoding of bulk samples is increasingly being implemented in ecosystem assessments and is more cost‐efficient and less time‐consuming than monitoring based on morphology. However, before raw sequences are obtained from bulk samples, a profound number of methodological choices must be made. Here, we critically review the recent methods used for metabarcoding of marine bulk samples (including benthic, plankton and diet samples) and indicate how potential biases can be introduced throughout sampling, preprocessing, DNA extraction, marker and primer selection, PCR amplification and sequencing. From a total of 64 studies evaluated, our recommendations for best practices include to (a) consider DESS as a fixative instead of ethanol, (b) use the DNeasy PowerSoil kit for any samples containing traces of sediment, (c) not limit the marker selection to COI only, but preferably include multiple markers for higher taxonomic resolution, (d) avoid touchdown PCR profiles, (e) use a fixed annealing temperature for each primer pair when comparing across studies or institutes, (f) use a minimum of three PCR replicates, and (g) include both negative and positive controls. Although the implementation of DNA metabarcoding still faces several technical complexities, we foresee wide‐ranging advances in the near future, including improved bioinformatics for taxonomic assignment, sequencing of longer fragments and the use of whole‐genome information. Despite the bulk of biases involved in metabarcoding of bulk samples, if appropriate controls are included along the data generation process, it is clear that DNA metabarcoding provides a valuable tool in ecosystem assessments.

Published

2020

38. Quality standard of traditional Chinese medicines: comparison between European Pharmacopoeia and Chinese Pharmacopoeia and recent advances

Author

Yuelin Song, Mei Wang, Peng-Fei Tu, Xue Hua, Tongkai Chen, Fong Leong, and Xiaojia Chen

Subjects

media_common.quotation_subject, Review, Traditional Chinese medicine, 01 natural sciences, law.invention, law, European Pharmacopoeia, Health care, Medicine, Quality (business), Chinese pharmacopoeia, media_common, Pharmacology, Traditional medicine, 010405 organic chemistry, business.industry, 010401 analytical chemistry, Chinese Pharmacopoeia, lcsh:Other systems of medicine, lcsh:RZ201-999, 0104 chemical sciences, Complementary and alternative medicine, Quality standard, Pharmacopoeia, business, Marker selection

Abstract

Traditional Chinese medicine (TCM) are becoming more and more popular all over the world. However, quality issues of TCM may lead to medical incidents in practice and therefore quality control is essential to TCM. In this review, the state of TCM in European Pharmacopoeia are compared with that in Chinese Pharmacopoeia, and herbal drugs that are not considered as TCM and not elaborated by TCM working party at European Directorate for the Quality of Medicines & Health Care (EDQM) but present in both European Pharmacopoeia and Chinese Pharmacopoeias are also discussed. Different aspects in quality control of TCM including origins, identification, tests and assays, as well as sample preparation, marker selection and TCM processing are covered to address the importance of establishing comprehensive quality standard of TCM. Furthermore, advanced analytical techniques for quality control and standard establishment of TCM are also reviewed. Electronic supplementary material The online version of this article (10.1186/s13020-020-00357-3) contains supplementary material, which is available to authorized users.

Published

2020

39. Mapping of QTLs controlling barley agronomic traits (Hordeum vulgare L.) under normal conditions and drought and salinity stress at reproductive stage

Author

Somayyeh Makhtoum, Hossein Sabouri, Abdollatif Gholizadeh, Leila Ahangar, Mahnaz Katouzi, and Andrea Mastinu

Subjects

Markers, Salinity, Drought, Barley, Genetics, Plant Science, Marker selection, Biochemistry, Biotechnology

Published

2022

40. Progress and potential of exosome analysis for early pancreatic cancer detection.

Author

Erb, Ulrike and Zöller, Margot

Abstract

Introduction: Pancreatic cancer (PaCa) is the most deadly malignancy, due to late diagnosis prohibiting surgery. Thus, strong efforts are taken improving early diagnosis via biomarkers recovered in the serum of PaCa patients. Areas covered: One promising option are PaCa-derived exosomes in patients’ sera. Exosomes, small vesicles delivered by live cells and recovered in all body fluids, are a powerful diagnostic tool due to relative stability and composition covering the whole range of cancer-related biomarkers including proteins, metabolites, DNA, DNA modifications, coding and noncoding RNA. We discuss the mechanisms accounting for the condensed packaging of biomarkers, refer to studies using PaCa serum-exosomes for diagnosis. Based on an extensive literature search, we outline questions that answers may help establishing a serum-exosome-based screening for early PaCa detection. Expert commentary: Improved proteomic and genomic characterization and progress in the biogenesis of exosomes will allow for optimized and unified screening panels for PaCa diagnosis via TEX in body fluids. [ABSTRACT FROM PUBLISHER]

Published

2016

41. The Development of Quality Control Genotyping Approaches: A Case Study Using Elite Maize Lines.

Author

Chen, Jiafa, Zavala, Cristian, Ortega, Noemi, Petroli, Cesar, Franco, Jorge, Burgueño, Juan, Costich, Denise E., and Hearne, Sarah J.

Subjects

*QUALITY control, *GENOTYPES, *QUALITY standards, *CORN, *PLANT germplasm

Abstract

Quality control (QC) of germplasm identity and purity is a critical component of breeding and conservation activities. SNP genotyping technologies and increased availability of markers provide the opportunity to employ genotyping as a low-cost and robust component of this QC. In the public sector available low-cost SNP QC genotyping methods have been developed from a very limited panel of markers of 1,000 to 1,500 markers without broad selection of the most informative SNPs. Selection of optimal SNPs and definition of appropriate germplasm sampling in addition to platform section impact on logistical and resource-use considerations for breeding and conservation applications when mainstreaming QC. In order to address these issues, we evaluated the selection and use of SNPs for QC applications from large DArTSeq data sets generated from CIMMYT maize inbred lines (CMLs). Two QC genotyping strategies were developed, the first is a “rapid QC”, employing a small number of SNPs to identify potential mislabeling of seed packages or plots, the second is a “broad QC”, employing a larger number of SNP, used to identify each germplasm entry and to measure heterogeneity. The optimal marker selection strategies combined the selection of markers with high minor allele frequency, sampling of clustered SNP in proportion to marker cluster distance and selecting markers that maintain a uniform genomic distribution. The rapid and broad QC SNP panels selected using this approach were further validated using blind test assessments of related re-generation samples. The influence of sampling within each line was evaluated. Sampling 192 individuals would result in close to 100% possibility of detecting a 5% contamination in the entry, and approximately a 98% probability to detect a 2% contamination of the line. These results provide a framework for the establishment of QC genotyping. A comparison of financial and time costs for use of these approaches across different platforms is discussed providing a framework for institutions involved in maize conservation and breeding to assess the resource use effectiveness of QC genotyping. Application of these research findings, in combination with existing QC approaches, will ensure the regeneration, distribution and use in breeding of true to type inbred germplasm. These findings also provide an effective approach to optimize SNP selection for QC genotyping in other species. [ABSTRACT FROM AUTHOR]

Published

2016

42. A Spectral-Spatial Classification of Hyperspectral Images Based on the Algebraic Multigrid Method and Hierarchical Segmentation Algorithm.

Author

Haiwei Song and Yi Wang

Subjects

*HYPERSPECTRAL imaging systems, *ALGEBRAIC multigrid methods, *IMAGE segmentation, *ROBUST control, *PARTIAL differential equations, *PIXELS

Abstract

The algebraic multigrid (AMG) method is used to solve linear systems of equations on a series of progressively coarser grids and has recently attracted significant attention for image segmentation due to its high efficiency and robustness. In this paper, a novel spectral-spatial classification method for hyperspectral images based on the AMG method and hierarchical segmentation (HSEG) algorithm is proposed. Our method consists of the following steps. First, the AMG method is applied to hyperspectral imagery to construct a multigrid structure of fine-to-coarse grids based on the anisotropic diffusion partial differential equation (PDE). The vertices in the multigrid structure are then considered as the initial seeds (markers) for growing regions and are clustered to obtain a sequence of segmentation results. In the next step, a maximum vote decision rule is employed to combine the pixel-wise classification map and the segmentation maps. Finally, a final classification map is produced by choosing the optimal grid level to extract representative spectra. Experiments based on three different types of real hyperspectral datasets with different resolutions and contexts demonstrate that our method can obtain 3.84%-13.81% higher overall accuracies than the SVM classifier. The performance of our method was further compared to several marker-based spectral-spatial classification methods using objective quantitative measures and a visual qualitative evaluation. [ABSTRACT FROM AUTHOR]

Published

2016

43. The impact of sample size and marker selection on the study of haplotype structures

Author

Sun Xiao, Stephens J, and Zhao Hongyu

Subjects

single nucleotide polymorphism (SNP), haplotype, sample size, marker selection, haplotype block, tag SNPs, Medicine, Genetics, QH426-470

Abstract

Abstract Several studies of haplotype structures in the human genome in various populations have found that the human chromosomes are structured such that each chromosome can be divided into many blocks, within which there is limited haplotype diversity. In addition, only a few genetic markers in a putative block are needed to capture most of the diversity within a block. There has been no systematic empirical study of the effects of sample size and marker set on the identified block structures and representative marker sets, however. The purpose of this study was to conduct a detailed empirical study to examine such impacts. Towards this goal, we have analysed three representative autosomal regions from a large genome-wide study of haplotypes with samples consisting of African-Americans and samples consisting of Japanese and Chinese individuals. For both populations, we have found that the sample size and marker set have significant impact on the number of blocks and the total number of representative markers identified. The marker set in particular has very strong impacts, and our results indicate that the marker density in the original datasets may not be adequate to allow a meaningful characterisation of haplotype structures. In general, we conclude that we need a relatively large sample size and a very dense marker panel in the study of haplotype structures in human populations.

Published

2004

44. A rank-based marker selection method for high throughput scRNA-seq data

Author

Vargo, Alexander H. S. and Gilbert, Anna C.

Published

2020

45. A COMPARISON STUDY OF DIFFERENT MARKER SELECTION METHODS FOR SPECTRAL-SPATIAL CLASSIFICATION OF HYPERSPECTRAL IMAGES.

Author

Akbari, D., Safari, A. R., Homayouni, S., and Khazai, S.

Subjects

SUPPORT vector machines, HYPERSPECTRAL imaging systems, IMAGE segmentation

Abstract

An effective approach based on the Minimum Spanning Forest (MSF), grown from automatically selected markers using Support Vector Machines (SVM), has been proposed for spectral-spatial classification of hyperspectral images by Tarabalka et al. This paper aims at improving this approach by using image segmentation to integrate the spatial information into marker selection process. In this study, the markers are extracted from the classification maps, obtained by both SVM and segmentation algorithms, and then are used to build the MSF. The segmentation algorithms are the watershed, expectation maximization (EM) and hierarchical clustering. These algorithms are used in parallel and independently to segment the image. Moreover, the pixels of each class, with the largest population in the classification map, are kept for each region of the segmentation map. Lastly, the most reliable classified pixels are chosen from among the exiting pixels as markers. Two benchmark urban hyperspectral datasets are used for evaluation: Washington DC Mall and Berlin. The results of our experiments indicate that, compared to the original MSF approach, the marker selection using segmentation algorithms leads in more accurate classification maps. [ABSTRACT FROM AUTHOR]

Published

2015

46. Classification of Remotely Sensed Images Using the GeneSIS Fuzzy Segmentation Algorithm.

Author

Mylonas, Stelios K., Stavrakoudis, Dimitris G., Theocharis, John B., and Mastorocostas, Paris A.

Subjects

*IMAGE segmentation, *ALGORITHMS, *GENETIC algorithms, *FUZZY algorithms, *DIGITAL image processing

Abstract

In this paper, we propose an integrated framework of the recently proposed Genetic Sequential Image Segmentation (GeneSIS) algorithm. GeneSIS segments the image in an iterative manner, whereby at each iteration, a single object is extracted via a genetic algorithm-based object extraction method. This module evaluates the fuzzy content of candidate regions, and through an effective fitness function design provides objects with optimal balance between fuzzy coverage, consistency and smoothness. GeneSIS exhibits a number of interesting properties, such as reduced over-/undersegmentation, adaptive search scale, and region-based search. To enhance the capabilities of GeneSIS, we incorporate here several improvements of our initial proposal. On one hand, two modifications are introduced pertaining to the object extraction algorithm. Specifically, we consider a more flexible representation of the structural elements used for the object's extraction. Furthermore, in view of its importance, the consistency criterion is redefined, thus providing a better handling of the ambiguous areas of the image. On the other hand we incorporate three tools properly devised, according to the fuzzy principles characterizing GeneSIS. First, we develop a marker selection strategy that creates reliable markers, particularly when dealing with ambiguous components of the image. Furthermore, using GeneSIS as the essential part, we consider a generalized experimental setup embracing two different classification schemes for remote sensing images: the spectral-spatial classification and the supervised segmentation methods. Finally, exploiting the inherent property of GeneSIS to produce multiple segmentations, we propose a segmentation fusion scheme. The effectiveness of the proposed methodology is validated after thorough experimentation on four data sets. [ABSTRACT FROM PUBLISHER]

Published

2015

47. THE FOREST FOR THE TREES: EVALUATING MOLECULAR PHYLOGENIES WITH AN EMPHASIS ON HIGHER-LEVEL DECAPODA.

Author

Timm, Laura and Bracken-Grissom, Heather D.

Subjects

DECAPODA, CRUSTACEAN phylogeny, MOLECULAR phylogeny, NUCLEOTIDE sequence, STATISTICAL sampling

Abstract

Since the late 1800s, several infraordinal relationships have been proposed for Decapoda; however, reaching a consensus among higher-level relationships is proving difficult. Molecular methods were first applied to higher-level decapod phylogenetics in the 1990s and have significantly contributed to our understanding of the group: sampling is becoming more thorough, a greater number of phylogenetically informative characters are being sequenced, and analysis procedures are becoming more consistent between studies. However, relationships among the deep lineages of Decapoda remain unclear. Several phylogenetic hypotheses have been suggested, and while there is some agreement among studies, an ultimate consensus among higher-level relationships has yet to be reached. This is largely the result of differences in sampling effort, marker selection, data-recycling, and analysis. Because most studies have generated conflicting phylogenetic hypotheses, the foundation on which the trees were built (data and analysis procedures) must be considered and evaluated. In this review, we summarize the early morphological decapod studies, address common problems that are causing a lack of consensus in molecular studies, present a means of evaluating molecular trees, offer suggestions for good phylogenetic practice, review the previous molecular studies of infraordinal decapod phylogeny, and discuss the future directions of the field, with special attention paid to next-generation sequencing (NGS) techniques. [ABSTRACT FROM AUTHOR]

Published

2015

48. International Barcode of Life: Evolution of a global research community.

Author

Adamowicz, Sarah J.

Subjects

*GENETIC barcoding, *FOOD chains, *CLIMATE change, *AGRICULTURAL pests, *QUARANTINE, *INTRODUCED species

Abstract

The 6th International Barcode of Life Conference (Guelph, Canada, 18-21 August 2015), themed Barcodes to Biomes, showcases the latest developments in DNA barcoding research and its diverse applications. The meeting also provides a venue for a global research community to share ideas and to initiate collaborations. All plenary and contributed abstracts are being published as an open-access special issue of Genome. Here, I use a comparison with the 3rd Conference (Mexico City, 2009) to highlight 10 recent and emerging trends that are apparent among the contributed abstracts. One of the outstanding trends is the rising proportion of abstracts that focus upon multiple socio-economically important applications of DNA barcoding, including studies of agricultural pests, quarantine and invasive species, wildlife forensics, disease vectors, biomonitoring of ecosystem health, and marketplace surveys evaluating the authenticity of seafood products and medicinal plants. Other key movements include the use of barcoding and metabarcoding approaches for dietary analyses--and for studies of food webs spanning three or more trophic levels--as well as the spread of next-generation sequencing methods in multiple contexts. In combination with the rising taxonomic and geographic scope of many barcoding iniatives, these developments suggest that several important questions in biology are becoming tractable. "What is this specimen on an agricultural shipment?", "Who eats whom in this whole food web?", and even "How many species are there?" are questions that may be answered in time periods ranging from a few years to one or a few decades. The next phases of DNA barcoding may expand yet further into prediction of community shifts with climate change and improved management of biological resources. [ABSTRACT FROM AUTHOR]

Published

2015

49. A Region-Based GeneSIS Segmentation Algorithm for the Classification of Remotely Sensed Images.

Author

Mylonas, Stelios K., Stavrakoudis, Dimitris G., Theocharis, John B., and Mastorocostas, Paris A.

Subjects

*IMAGE segmentation, *WATERSHED ecology, *GENETIC algorithms, *PIXELS, *HOMOGENEITY

Abstract

This paper proposes an object-based segmentation/classification scheme for remotely sensed images, based on a novel variant of the recently proposed Genetic Sequential Image Segmentation (GeneSIS) algorithm. GeneSIS segments the image in an iterative manner, whereby at each iteration a single object is extracted via a genetic-based object extraction algorithm. Contrary to the previous pixel-based GeneSIS where the candidate objects to be extracted were evaluated through the fuzzy content of their included pixels, in the newly developed region-based GeneSIS algorithm, a watershed-driven fine segmentation map is initially obtained from the original image, which serves as the basis for the forthcoming GeneSIS segmentation. Furthermore, in order to enhance the spatial search capabilities, we introduce a more descriptive encoding scheme in the object extraction algorithm, where the structural search modules are represented by polygonal shapes. Our objectives in the new framework are posed as follows: enhance the flexibility of the algorithm in extracting more flexible object shapes, assure high level classification accuracies, and reduce the execution time of the segmentation, while at the same time preserving all the inherent attributes of the GeneSIS approach. Finally, exploiting the inherent attribute of GeneSIS to produce multiple segmentations, we also propose two segmentation fusion schemes that operate on the ensemble of segmentations generated by GeneSIS. Our approaches are tested on an urban and two agricultural images. The results show that region-based GeneSIS has considerably lower computational demands compared to the pixel-based one. Furthermore, the suggested methods achieve higher classification accuracies and good segmentation maps compared to a series of existing algorithms. [ABSTRACT FROM AUTHOR]

Published

2015

50. Integrative analysis of '-omics' data using penalty functions.

Author

Zhao, Qing, Shi, Xingjie, Huang, Jian, Liu, Jin, Li, Yang, and Ma, Shuangge

Subjects

*META-analysis, *LAPLACIAN matrices, *REGULARIZATION parameter, *MATHEMATICAL variables, *ALGORITHMS, *DATA integration, *BIOMARKERS

Abstract

In the analysis of omics data, integrative analysis provides an effective way of pooling information across multiple datasets or multiple correlated responses, and can be more effective than single dataset (response) analysis. Multiple families of integrative analysis methods have been proposed in the literature. The current review focuses on the penalization methods. Special attention is paid to sparse meta-analysis methods that pool summary statistics across datasets, and integrative analysis methods that pool raw data across datasets. We discuss their formulation and rationale. Beyond 'standard' penalized selection, we also review contrasted penalization and Laplacian penalization that accommodate finer data structures. The computational aspects, including computational algorithms and tuning parameter selection, are examined. This review concludes with possible limitations and extensions. WIREs Comput Stat 2015, 7:99-108. doi: 10.1002/wics.1322 For further resources related to this article, please visit the . Conflict of interest: The authors have declared no conflicts of interest for this article. [ABSTRACT FROM AUTHOR]

Published

2015