Your search keyword '"Lebo, Matthew S."' showing total 5 results

1. Multiple GYPB gene deletions associated with the U− phenotype in those of African ancestry

Author

Lane, William J., primary, Gleadall, Nicholas S., additional, Aeschlimann, Judith, additional, Vege, Sunitha, additional, Sanchis‐Juan, Alba, additional, Stephens, Jonathan, additional, Cone Sullivan, Jensyn, additional, Mah, Helen H., additional, Aguad, Maria, additional, Smeland‐Wagman, Robin, additional, Lebo, Matthew S., additional, Vijay Kumar, Prathik K., additional, Kaufman, Richard M., additional, Green, Robert C., additional, Ouwehand, Willem H., additional, and Westhoff, Connie M., additional

Published

2020

2. Automated typing of red blood cell and platelet antigens from whole exome sequences.

Author

Lane, William J., Vege, Sunitha, Mah, Helen H., Lomas‐Francis, Christine, Aguad, Maria, Smeland‐Wagman, Robin, Koch, Christopher, Killian, Jacqueline M., Gardner, Cubby L., De Castro, Mauricio, Lebo, Matthew S., Kaufman, Richard M., Green, Robert C., Westhoff, Connie M., Lomas-Francis, Christine, Smeland-Wagman, Robin, and MilSeq Project

Subjects

ERYTHROCYTES, BLOOD platelets, BLOOD groups, ANTIGENS, POLYMERASE chain reaction

Abstract

Background: Genotyping has expanded the number red blood cell (RBC) and platelet (PLT) antigens that can readily be typed, but often represents an additional testing cost. The analysis of existing genomic data offers a cost-effective approach. We recently developed automated software (bloodTyper) for determination of RBC and PLT antigens from whole genome sequencing. Here we extend the algorithm to whole exome sequencing (WES).Study Design and Methods: Whole exome sequencing was performed on samples from 75 individuals. WES-based bloodTyper RBC and PLT typing was compared to conventional polymerase chain reaction (PCR) RHD zygosity testing and serologic and single-nucleotide polymorphism (SNP) typing for 38 RBC antigens in 12 systems (17 serologic and 35 SNPs) and 22 PLT antigens (22 SNPs). Samples from the first 20 individuals were used to modify bloodTyper to interpret WES followed by blinded typing of 55 samples.Results: Over the first 20 samples, discordances were noted for C, M, and N antigens, which were due to WES-specific biases. After modification, bloodTyper was 100% accurate on blinded evaluation of the last 55 samples and outperformed both serologic (99.67% accurate) and SNP typing (99.97% accurate) reflected by two Fyb and one N serologic typing errors and one undetected SNP encoding a Jknull phenotype. RHD zygosity testing by bloodTyper was 100% concordant with a combination of hybrid Rhesus box PCR and PCR-restriction fragment length polymorphism for all samples.Conclusion: The automated bloodTyper software was modified for WES biases to allow for accurate RBC and PLT antigen typing. Such analysis could become a routing part of future WES efforts. [ABSTRACT FROM AUTHOR]

Published

2019

3. A whole genome approach for discovering the genetic basis of blood group antigens: independent confirmation for P1 and Xga.

Author

Lane, William J., Aguad, Maria, Smeland‐Wagman, Robin, Vege, Sunitha, Mah, Helen H., Joseph, Abigail, Blout, Carrie L., Nguyen, Tiffany T., Lebo, Matthew S., Sidhu, Manpreet, Lomas‐Francis, Christine, Kaufman, Richard M., Green, Robert C., Westhoff, Connie M., Bates, David W., Blout, Carrie, Christensen, Kurt D., Cirino, Allison L., Ho, Carolyn Y., and Krier, Joel B.

Subjects

Y chromosome, BLOOD group antigens, TRANSCRIPTION factors, NUCLEOTIDE sequencing

Abstract

Background: Although P1 and Xga are known to be associated with the A4GALT and XG genes, respectively, the genetic basis of antigen expression has been elusive. Recent reports link both P1 and Xga expression with nucleotide changes in the promotor regions and with antigen-negative phenotypes due to disruption of transcription factor binding.Study Design and Methods: Whole genome sequencing was performed on 113 individuals as part of the MedSeq Project with serologic RBC antigen typing for P1 (n = 77) and Xga (n = 15). Genomic data were analyzed by two approaches, nucleotide frequency correlation and serologic correlation, to find A4GALT and XG changes associated with P1 and Xga expression.Results: For P1, the frequency approach identified 29 possible associated nucleotide changes, and the serologic approach revealed four among them correlating with the P1+/P1- phenotype: chr22:43,115,523_43,115,520AAAG/delAAAG (rs66781836); chr 22:43,114,551C/T (rs8138197); chr22:43,114,020 T/G (rs2143918); and chr22:43,113,793G/T (rs5751348). For Xga , the frequency approach identified 82 possible associated nucleotide changes, and among these the serologic approach revealed one correlating with the Xg(a+)/Xg(a-) phenotype: chrX:2,666,384G/C (rs311103).Conclusion: A bioinformatics analysis pipeline was created to identify genetic changes responsible for RBC antigen expression. This study, in progress before the recently published reports, independently confirms the basis for P1 and Xga . Although this enabled molecular typing of these antigens, the Y chromosome PAR1 region interfered with Xga typing in males. This approach could be used to identify and confirm the genetic basis of antigens, potentially replacing the historical approach using family pedigrees as genomic sequencing becomes commonplace. [ABSTRACT FROM AUTHOR]

Published

2019

4. A whole genome approach for discovering the genetic basis of blood group antigens: independent confirmation for P1 and Xga.

Author

Lane, William J., Aguad, Maria, Smeland‐Wagman, Robin, Vege, Sunitha, Mah, Helen H., Joseph, Abigail, Blout, Carrie L., Nguyen, Tiffany T., Lebo, Matthew S., Sidhu, Manpreet, Lomas‐Francis, Christine, Kaufman, Richard M., Green, Robert C., Westhoff, Connie M., Bates, David W., Blout, Carrie, Christensen, Kurt D., Cirino, Allison L., Ho, Carolyn Y., and Krier, Joel B.

Subjects

*Y chromosome, *BLOOD group antigens, *TRANSCRIPTION factors, *NUCLEOTIDE sequencing

Abstract

Background: Although P1 and Xga are known to be associated with the A4GALT and XG genes, respectively, the genetic basis of antigen expression has been elusive. Recent reports link both P1 and Xga expression with nucleotide changes in the promotor regions and with antigen-negative phenotypes due to disruption of transcription factor binding.Study Design and Methods: Whole genome sequencing was performed on 113 individuals as part of the MedSeq Project with serologic RBC antigen typing for P1 (n = 77) and Xga (n = 15). Genomic data were analyzed by two approaches, nucleotide frequency correlation and serologic correlation, to find A4GALT and XG changes associated with P1 and Xga expression.Results: For P1, the frequency approach identified 29 possible associated nucleotide changes, and the serologic approach revealed four among them correlating with the P1+/P1- phenotype: chr22:43,115,523_43,115,520AAAG/delAAAG (rs66781836); chr 22:43,114,551C/T (rs8138197); chr22:43,114,020 T/G (rs2143918); and chr22:43,113,793G/T (rs5751348). For Xga , the frequency approach identified 82 possible associated nucleotide changes, and among these the serologic approach revealed one correlating with the Xg(a+)/Xg(a-) phenotype: chrX:2,666,384G/C (rs311103).Conclusion: A bioinformatics analysis pipeline was created to identify genetic changes responsible for RBC antigen expression. This study, in progress before the recently published reports, independently confirms the basis for P1 and Xga . Although this enabled molecular typing of these antigens, the Y chromosome PAR1 region interfered with Xga typing in males. This approach could be used to identify and confirm the genetic basis of antigens, potentially replacing the historical approach using family pedigrees as genomic sequencing becomes commonplace. [ABSTRACT FROM AUTHOR]

Published

2019

5. A whole genome approach for discovering the genetic basis of blood group antigens: independent confirmation for P1 and Xg a .

Author

Lane WJ, Aguad M, Smeland-Wagman R, Vege S, Mah HH, Joseph A, Blout CL, Nguyen TT, Lebo MS, Sidhu M, Lomas-Francis C, Kaufman RM, Green RC, and Westhoff CM

Subjects

Alleles, Computational Biology methods, Galactosyltransferases genetics, Genotype, Humans, Phenotype, Polymorphism, Single Nucleotide genetics, Blood Group Antigens genetics, Whole Genome Sequencing methods

Abstract

Background: Although P1 and Xg a are known to be associated with the A4GALT and XG genes, respectively, the genetic basis of antigen expression has been elusive. Recent reports link both P1 and Xg a expression with nucleotide changes in the promotor regions and with antigen-negative phenotypes due to disruption of transcription factor binding., Study Design and Methods: Whole genome sequencing was performed on 113 individuals as part of the MedSeq Project with serologic RBC antigen typing for P1 (n = 77) and Xg a (n = 15). Genomic data were analyzed by two approaches, nucleotide frequency correlation and serologic correlation, to find A4GALT and XG changes associated with P1 and Xg a expression., Results: For P1, the frequency approach identified 29 possible associated nucleotide changes, and the serologic approach revealed four among them correlating with the P1+/P1- phenotype: chr22:43,115,523_43,115,520AAAG/delAAAG (rs66781836); chr 22:43,114,551C/T (rs8138197); chr22:43,114,020 T/G (rs2143918); and chr22:43,113,793G/T (rs5751348). For Xg a , the frequency approach identified 82 possible associated nucleotide changes, and among these the serologic approach revealed one correlating with the Xg(a+)/Xg(a-) phenotype: chrX:2,666,384G/C (rs311103)., Conclusion: A bioinformatics analysis pipeline was created to identify genetic changes responsible for RBC antigen expression. This study, in progress before the recently published reports, independently confirms the basis for P1 and Xg a . Although this enabled molecular typing of these antigens, the Y chromosome PAR1 region interfered with Xg a typing in males. This approach could be used to identify and confirm the genetic basis of antigens, potentially replacing the historical approach using family pedigrees as genomic sequencing becomes commonplace., (© 2018 AABB.)

Published

2019