Your search keyword '"Godinez, Ricardo"' showing total 16 results

1. Adenosine augments the production of IL-10 in cervical cancer cells through interaction with the A2B adenosine receptor, resulting in protection against the activity of cytotoxic T cells

Author

Torres-Pineda, Daniela Berenice, Mora-García, María de Lourdes, García-Rocha, Rosario, Hernández-Montes, Jorge, Weiss-Steider, Benny, Montesinos-Montesinos, Juan José, Don-López, Christian Azucena, Marín-Aquino, Luis Antonio, Muñóz-Godínez, Ricardo, Ibarra, Luis Roberto Ávila, López Romero, Ricardo, and Monroy-García, Alberto

Published

2020

2. Experiential Learning Spaces Through an Academic Software Application to Simulate Production Lines of Rigid Bodies

Author

Morano-Okuno, Hector Rafael, primary, Chong-Quero, J. Enrique, additional, Esqueda-Merino, Donovan M., additional, Jaramillo-Godinez, Ricardo, additional, Tonix-Cuahutle, Yuliana, additional, and Murano-Labastida, Daishi Alfredo, additional

Published

2024

3. Prompt my prototype: NaiVE Framework for Artificial Intelligence use in Engineering Product Development

Author

Esqueda Merino, Donovan, primary, Gómez Meneses, Oliver, additional, Rafael Morano Okuno, Hector, additional, Jaramillo Godinez, Ricardo, additional, A Murano Labastida, Daishi, additional, De Los Angeles Ramos Solano, María, additional, Higuera Rosales, David, additional, Caltenco Castillo, Rafael, additional, Rodríguez Gómez, Karla, additional, and Díaz De León Rodríguez, Iván, additional

Published

2024

4. Developing anthropometrics competency-based learning with a simplified CAD model of a person

Author

Tónix Cuahutle, Yuliana, primary, Esqueda Merino, Donovan, additional, Jaramillo Godinez, Ricardo, additional, Rafael Morano Okuno, Hector, additional, Enrique Villagómez Guerrero, Luis, additional, and Gómez Meneses, Oliver, additional

Published

2024

5. Exploring a software application to simulate rigid bodies to have fast conceptual designs

Author

Rafael Morano-okuno, Hector, primary, Enrique Chong Quero, J, additional, and Jaramillo Godinez, Ricardo, additional

Published

2023

6. Corrigendum to “Adenosine augments the production of IL-10 in cervical cancer cells through interaction with the A2B adenosine receptor, resulting in protection against the activity of cytotoxic T cells” [Cytokine 130 (2020) 155082]

Author

Torres-Pineda, Daniela Berenice, de Lourdes Mora-García, María, García-Rocha, Rosario, Hernández-Montes, Jorge, Weiss-Steider, Benny, Montesinos-Montesinos, Juan José, Don-López, Christian Azucena, Marín-Aquino, Luis Antonio, Muñóz-Godínez, Ricardo, Ibarra, Luis Roberto Ávila, Romero, Ricardo López, and Monroy-García, Alberto

Published

2020

7. Gene duplication and fragmentation in the zebra finch major histocompatibility complex

Author

Burt David W, Kotkiewicz Holly, Godinez Ricardo, Westerdahl Helena, Völker Martin, Ekblom Robert, Balakrishnan Christopher N, Graves Tina, Griffin Darren K, Warren Wesley C, and Edwards Scott V

Subjects

Biology (General), QH301-705.5

Abstract

Abstract Background Due to its high polymorphism and importance for disease resistance, the major histocompatibility complex (MHC) has been an important focus of many vertebrate genome projects. Avian MHC organization is of particular interest because the chicken Gallus gallus, the avian species with the best characterized MHC, possesses a highly streamlined minimal essential MHC, which is linked to resistance against specific pathogens. It remains unclear the extent to which this organization describes the situation in other birds and whether it represents a derived or ancestral condition. The sequencing of the zebra finch Taeniopygia guttata genome, in combination with targeted bacterial artificial chromosome (BAC) sequencing, has allowed us to characterize an MHC from a highly divergent and diverse avian lineage, the passerines. Results The zebra finch MHC exhibits a complex structure and history involving gene duplication and fragmentation. The zebra finch MHC includes multiple Class I and Class II genes, some of which appear to be pseudogenes, and spans a much more extensive genomic region than the chicken MHC, as evidenced by the presence of MHC genes on each of seven BACs spanning 739 kb. Cytogenetic (FISH) evidence and the genome assembly itself place core MHC genes on as many as four chromosomes with TAP and Class I genes mapping to different chromosomes. MHC Class II regions are further characterized by high endogenous retroviral content. Lastly, we find strong evidence of selection acting on sites within passerine MHC Class I and Class II genes. Conclusion The zebra finch MHC differs markedly from that of the chicken, the only other bird species with a complete genome sequence. The apparent lack of synteny between TAP and the expressed MHC Class I locus is in fact reminiscent of a pattern seen in some mammalian lineages and may represent convergent evolution. Our analyses of the zebra finch MHC suggest a complex history involving chromosomal fission, gene duplication and translocation in the history of the MHC in birds, and highlight striking differences in MHC structure and organization among avian lineages.

Published

2010

8. Additional file 1 of Genomic legacy of the African cheetah, Acinonyx jubatus

Author

Dobrynin, Pavel, Shiping Liu, Gaik Tamazian, Zijun Xiong, Yurchenko, Andrey, Krasheninnikova, Ksenia, Kliver, Sergey, Schmidt-Küntzel, Anne, Klaus-Peter Koepfli, Johnson, Warren, Kuderna, Lukas, GarcíA-Pérez, Raquel, Manuel, Marc, Godinez, Ricardo, Komissarov, Aleksey, Makunin, Alexey, Brukhin, Vladimir, Weilin Qiu, Zhou, Long, Li, Fang, Yi, Jian, Driscoll, Carlos, Antunes, Agostinho, Oleksyk, Taras, Eizirik, Eduardo, Perelman, Polina, Roelke, Melody, Wildt, David, Diekhans, Mark, Marques-Bonet, Tomas, Marker, Laurie, Bhak, Jong, Wang, Jun, Guojie Zhang, and O’Brien, Stephen

Abstract

Supplemental figures. Figure S1. Cheetah genome size estimation by 17-mers. Figure S2. Depth distribution of cheetah reads. Figure S3. GC content and average sequencing depth values. Figure S4. Depth distribution of re-sequencing reads. Figure S5. Distribution of syntenic blocks in genome windows. Figure S6. Ten largest cat-cheetah rearrangements. Figure S7. Size of homozygosity stretches in Felidae genomes. Figure S8. Ideograms of homozygosity regions. Figure S9. Comparison of cheetah and human MHC regions. Figure S10. Comparison of cheetah and dog MHC regions. Figure S11. Inferred historical population sizes by PSMC analysis. Figure S12. Bootstrap values for DaDi demographic models. Figure S13. Alignments of the AKAP4 gene. Figure S14. Evolutionary history of LDH gene families. Figure S15. Cumulative distribution of 36-mers. Figure S16. Copy-number distribution in control regions. Figure S17. Example of fixed duplications on scaffold606. (PDF 2027 kb)

Published

2015

9. Genomic legacy of the African cheetah, Acinonyx jubatus

Author

Dobrynin, Pavel, Liu, Shiping, Tamazian, Gaik, Xiong, Zijun, Yurchenko, Andrey A., Krasheninnikova, Ksenia, Kliver, Sergey, Schmidt-Kuentzel, Anne, Koepfli, Klaus-Peter, Johnson, Warren, Kuderna, Lukas F. K., Garcia-Perez, Raquel, de Manuel, Marc, Godinez, Ricardo, Komissarov, Aleksey, Makunin, Alexey, Brukhin, Vladimir, Qiu, Weilin, Zhou, Long, Li, Fang, Yi, Jian, Driscoll, Carlos, Antunes, Agostinho, Oleksyk, Taras K., Eizirik, Eduardo, Perelman, Polina, Roelke, Melody, Wildt, David, Diekhans, Mark, Marques-Bonet, Tomas, Marker, Laurie, Bhak, Jong, Wang, Jun, Zhang, Guojie, O'Brien, Stephen J., Dobrynin, Pavel, Liu, Shiping, Tamazian, Gaik, Xiong, Zijun, Yurchenko, Andrey A., Krasheninnikova, Ksenia, Kliver, Sergey, Schmidt-Kuentzel, Anne, Koepfli, Klaus-Peter, Johnson, Warren, Kuderna, Lukas F. K., Garcia-Perez, Raquel, de Manuel, Marc, Godinez, Ricardo, Komissarov, Aleksey, Makunin, Alexey, Brukhin, Vladimir, Qiu, Weilin, Zhou, Long, Li, Fang, Yi, Jian, Driscoll, Carlos, Antunes, Agostinho, Oleksyk, Taras K., Eizirik, Eduardo, Perelman, Polina, Roelke, Melody, Wildt, David, Diekhans, Mark, Marques-Bonet, Tomas, Marker, Laurie, Bhak, Jong, Wang, Jun, Zhang, Guojie, and O'Brien, Stephen J.

Published

2015

10. Genomic legacy of the African cheetah, Acinonyx jubatus

Author

Dobrynin, Pavel, primary, Liu, Shiping, additional, Tamazian, Gaik, additional, Xiong, Zijun, additional, Yurchenko, Andrey A., additional, Krasheninnikova, Ksenia, additional, Kliver, Sergey, additional, Schmidt-Küntzel, Anne, additional, Koepfli, Klaus-Peter, additional, Johnson, Warren, additional, Kuderna, Lukas F.K., additional, García-Pérez, Raquel, additional, Manuel, Marc de, additional, Godinez, Ricardo, additional, Komissarov, Aleksey, additional, Makunin, Alexey, additional, Brukhin, Vladimir, additional, Qiu, Weilin, additional, Zhou, Long, additional, Li, Fang, additional, Yi, Jian, additional, Driscoll, Carlos, additional, Antunes, Agostinho, additional, Oleksyk, Taras K., additional, Eizirik, Eduardo, additional, Perelman, Polina, additional, Roelke, Melody, additional, Wildt, David, additional, Diekhans, Mark, additional, Marques-Bonet, Tomas, additional, Marker, Laurie, additional, Bhak, Jong, additional, Wang, Jun, additional, Zhang, Guojie, additional, and O’Brien, Stephen J., additional

Published

2015

11. Comparative genome analyses reveal distinct structure in the saltwater crocodile MHC

Author

Jaratlerdsiri, Weerachai, Deakin, Janine, Godinez, Ricardo M., Shan, Xueyan, Peterson, Daniel G., Marthey, Sylvain, Lyons, Eric, McCarthy, Fiona M., Isberg, Sally R., Higgins, Damien P., Chong, Amanda Y., John, John St, Glenn, Travis C., Ray, David A., Gongora, Jaime, Jaratlerdsiri, Weerachai, Deakin, Janine, Godinez, Ricardo M., Shan, Xueyan, Peterson, Daniel G., Marthey, Sylvain, Lyons, Eric, McCarthy, Fiona M., Isberg, Sally R., Higgins, Damien P., Chong, Amanda Y., John, John St, Glenn, Travis C., Ray, David A., and Gongora, Jaime

Abstract

The major histocompatibility complex (MHC) is a dynamic genome region with an essential role in the adaptive immunity of vertebrates, especially antigen presentation. The MHC is generally divided into (classes I, II and III) containing genes of similar function across species, but with different gene number and organisation. Crocodylia (crocodilians) are widely distributed and represent an evolutionary distinct group among higher vertebrates, but the genomic organisation of MHC within this lineage has been largely unexplored. Here, we studied the MHC region of the saltwater crocodile (Crocodylus porosus) and compared it with that of other taxa. We characterised genomic clusters encompassing MHC class I and class II genes in the saltwater crocodile based on sequencing of bacterial artificial chromosomes. Six gene clusters spanning ∼452 kb were identified to contain nine MHC class I genes, six MHC class II genes, three TAP genes, and a TRIM gene. These MHC class I and class II genes were in separate scaffold regions and were greater in length (2-6 times longer) than their counterparts in well-studied fowl B loci, suggesting that the compaction of avian MHC occurred after the crocodilian-avian split. Comparative analyses between the saltwater crocodile MHC and that from the alligator and gharial showed large syntenic areas (>80% identity) with similar gene order. Comparisons with other vertebrates showed that the saltwater crocodile had MHC class I genes located along with TAP, consistent with birds studied. Linkage between MHC class I and TRIM39 observed in the saltwater crocodile resembled MHC in eutherians compared, but absent in avian MHC, suggesting that the saltwater crocodile MHC appears to have gene organisation intermediate between these two lineages. These observations suggest that the structure of the saltwater crocodile MHC, and other crocodilians, can help determine the MHC that was present in the ancestors of archosaurs.

Published

2014

12. Comparative Genome Analyses Reveal Distinct Structure in the Saltwater Crocodile MHC

Author

Jaratlerdsiri, Weerachai, primary, Deakin, Janine, additional, Godinez, Ricardo M., additional, Shan, Xueyan, additional, Peterson, Daniel G., additional, Marthey, Sylvain, additional, Lyons, Eric, additional, McCarthy, Fiona M., additional, Isberg, Sally R., additional, Higgins, Damien P., additional, Chong, Amanda Y., additional, John, John St, additional, Glenn, Travis C., additional, Ray, David A., additional, and Gongora, Jaime, additional

Published

2014

13. Gene duplication and fragmentation in the zebra finch major histocompatibility complex

Author

Balakrishnan, Christopher N., Ekblom, Robert, Voelker, Martin, Westerdahl, Helena, Godinez, Ricardo, Kotkiewicz, Holly, Burt, David W., Graves, Tina, Griffin, Darren K., Warren, Wesley C., Edwards, Scott V., Balakrishnan, Christopher N., Ekblom, Robert, Voelker, Martin, Westerdahl, Helena, Godinez, Ricardo, Kotkiewicz, Holly, Burt, David W., Graves, Tina, Griffin, Darren K., Warren, Wesley C., and Edwards, Scott V.

Abstract

Background: Due to its high polymorphism and importance for disease resistance, the major histocompatibility complex (MHC) has been an important focus of many vertebrate genome projects. Avian MHC organization is of particular interest because the chicken Gallus gallus, the avian species with the best characterized MHC, possesses a highly streamlined minimal essential MHC, which is linked to resistance against specific pathogens. It remains unclear the extent to which this organization describes the situation in other birds and whether it represents a derived or ancestral condition. The sequencing of the zebra finch Taeniopygia guttata genome, in combination with targeted bacterial artificial chromosome (BAC) sequencing, has allowed us to characterize an MHC from a highly divergent and diverse avian lineage, the passerines. Results: The zebra finch MHC exhibits a complex structure and history involving gene duplication and fragmentation. The zebra finch MHC includes multiple Class I and Class II genes, some of which appear to be pseudogenes, and spans a much more extensive genomic region than the chicken MHC, as evidenced by the presence of MHC genes on each of seven BACs spanning 739 kb. Cytogenetic (FISH) evidence and the genome assembly itself place core MHC genes on as many as four chromosomes with TAP and Class I genes mapping to different chromosomes. MHC Class II regions are further characterized by high endogenous retroviral content. Lastly, we find strong evidence of selection acting on sites within passerine MHC Class I and Class II genes. Conclusion: The zebra finch MHC differs markedly from that of the chicken, the only other bird species with a complete genome sequence. The apparent lack of synteny between TAP and the expressed MHC Class I locus is in fact reminiscent of a pattern seen in some mammalian lineages and may represent convergent evolution. Our analyses of the zebra finch MHC suggest a complex history involving chromosomal fission, gene dupli

Published

2010

14. Gene duplication and fragmentation in the zebra finch major histocompatibility complex

Author

Balakrishnan, Christopher N, primary, Ekblom, Robert, additional, Völker, Martin, additional, Westerdahl, Helena, additional, Godinez, Ricardo, additional, Kotkiewicz, Holly, additional, Burt, David W, additional, Graves, Tina, additional, Griffin, Darren K, additional, Warren, Wesley C, additional, and Edwards, Scott V, additional

Published

2010

15. Gene duplication and fragmentation in the zebrafinch major histocompatibility complex.

Author

Balakrishnan, Christopher N., Ekblom, Robert, Völker, Martin, Westerdahl, Helena, Godinez, Ricardo, Kotkiewicz, Holly, Burt, David W., Graves, Tina, Griffin, Darren K., Warren, Wesley C., and Edwards, Scott V.

Subjects

ZEBRA finch, BACTERIAL artificial chromosomes, MAJOR histocompatibility complex, POLYMORPHISM (Zoology), CHICKENS, TAENIOPYGIA

Abstract

Background: Due to its high polymorphism and importance for disease resistance, the major histocompatibility complex (MHC) has been an important focus of many vertebrate genome projects. Avian MHC organization is of particular interest because the chicken Gallus gallus, the avian species with the best characterized MHC, possesses a highly streamlined minimal essential MHC, which is linked to resistance against specific pathogens. It remains unclear the extent to which this organization describes the situation in other birds and whether it represents a derived or ancestral condition. The sequencing of the zebra finch Taeniopygia guttata genome, in combination with targeted bacterial artificial chromosome (BAC) sequencing, has allowed us to characterize an MHC from a highly divergent and diverse avian lineage, the passerines. Results: The zebra finch MHC exhibits a complex structure and history involving gene duplication and fragmentation. The zebra finch MHC includes multiple Class I and Class II genes, some of which appear to be pseudogenes, and spans a much more extensive genomic region than the chicken MHC, as evidenced by the presence of MHC genes on each of seven BACs spanning 739 kb. Cytogenetic (FISH) evidence and the genome assembly itself place core MHC genes on as many as four chromosomes with TAP and Class I genes mapping to different chromosomes. MHC Class II regions are further characterized by high endogenous retroviral content. Lastly, we find strong evidence of selection acting on sites within passerine MHC Class I and Class II genes. Conclusion: The zebra finch MHC differs markedly from that of the chicken, the only other bird species with a complete genome sequence. The apparent lack of synteny between TAP and the expressed MHC Class I locus is in fact reminiscent of a pattern seen in some mammalian lineages and may represent convergent evolution. Our analyses of the zebra finch MHC suggest a complex history involving chromosomal fission, gene duplication and translocation in the history of the MHC in birds, and highlight striking differences in MHC structure and organization among avian lineages. [ABSTRACT FROM AUTHOR]

Published

2010

16. Comparative Genomics of the Major Histocompatibility Complex in Amniotes

Author

Godinez, Ricardo and Edwards, Scott V.

Subjects

Biology, Immunology, Evolution & development, Amniotes, Birds Mammals and Reptiles, Comparative genomics, Evolution, Major Histocompatibility Complex, MHC

Abstract

The major histocompatibility complex region (MHC) is a multi gene family present in all jawed vertebrates, with a fundamental role in vertebrate immunity. More than two decades of studies have resulted in the characterization of over a dozen MHC regions, and models of evolution explaining that the MHC has gradually increased in size and gene content since its origins without addressing their genomic context or the environmental selective forces. Furthermore, a compelling reconstruction of the evolutionary history of the MHC has been hampered due to phylogenetic gaps and the absence of comparative phylogenetic methods applied to comparative genomics. Here I reconstruct 320 MY of MHC evolution using 42 amniote genomes using improved gene annotations, genomic alignments and phylogenetic algorithms to reconstruct the evolution of the MHC at three levels of phylogenetic resolution. The first one describes 25 MY of evolution of the primate MHC using eight Human and four non-Human primate MHC haplotypes. Results suggests that highly dense gene segments have a strikingly conserved gene organization, and six conserved and highly rearranging segments overlap genes that are most commonly associated to disease. Phylogenomic analysis implies that the MHC has remained stable in gene content and size, with significantly increased duplication rates in the primate ancestors. The second one describes 280 MY of MHC evolution through the first characterization of reptilian MHC region, which combines mammalian, reptilian, Bird and amphibian characteristics, which favors the hypothesis of the existence of a primordial MHC in which natural killer receptors, CD1 and lectin genes co-exist. The Anolis MHC expands our understanding of the origins of the exceptionally small Bird MHC regions and provides further information about the organization and size of the ancestral amniote MHC. The third one compares 42 amniote MHC regions and map gene duplications and losses to further evaluate the mode and tempo of the evolution of the region. Comparative phylogenetic methods imply that the genomic and environmental factors affect the diversification of MHC during 320 My of evolution.

Published

2013