Your search keyword '"Lopez GH"' showing total 30 results

1. The effect of using different levels of shrimp meal in broiler diets

Author

Rosenfeld, DJ, Gernat, AG, Marcano, JD, Murillo, JG, Lopez, GH, and Flores, JA

Published

1997

2. A cold case of hemolytic disease of the fetus and newborn resolved by genomic sequencing and population studies to define a new antigen in the Rh system.

Author

Wilson B, Davison CL, Lopez GH, Millard GM, Liew YW, Powley T, Campbell T, Jadhao SS, Nagaraj SH, Perry M, Roulis EV, Toombs M, Irving DO, Flower RL, and Hyland CA

Subjects

Humans, Female, Infant, Newborn, Pregnancy, Male, Adult, Isoantibodies blood, Isoantibodies immunology, Alleles, Erythrocytes immunology, Polymorphism, Single Nucleotide, Rh-Hr Blood-Group System genetics, Rh-Hr Blood-Group System immunology, Erythroblastosis, Fetal genetics, Erythroblastosis, Fetal immunology

Abstract

Background: We report an obstetric case involving an RhD-positive woman who had developed a red blood cell (RBC) antibody that was not detected until after delivery of a newborn, who presented with a positive direct antiglobulin test result. Immunohematology studies suggested that the maternal antibody was directed against a low-prevalence antigen on the paternal and newborn RBCs., Results: Comprehensive blood group profiling by targeted exome sequencing revealed a novel nonsynonymous single nucleotide variant (SNV) RHCE c.486C>G (GenBank MZ326705) on the RHCE*Ce allele, for both the father and newborn. A subsequent genomic-based study to profile blood groups in an Indigenous Australian population revealed the same SNV in 2 of 247 individuals. Serology testing showed that the maternal antibody reacted specifically with RBCs from these two individuals., Discussion: The maternal antibody was directed against a novel antigen in the Rh blood group system arising from an RHCE c.486C>G variant on the RHCE*Ce allele linked to RHD*01. The variant predicts a p.Asn162Lys change on the RhCE protein and has been registered as the 56th antigen in the Rh system, ISBT RH 004063., Conclusion: This antibody was of clinical significance, resulting in a mild to moderate hemolytic disease of the fetus and newborn (HDFN). In the past, the cause of such HDFN cases may have remained unresolved. Genomic sequencing combined with population studies now assists in resolving such cases. Further population studies have potential to inform the need to design population-specific red cell antibody typing panels for antibody screening in the Australian population., (© 2022 AABB.)

Published

2024

3. Anti-N antibody mimicking an antibody to a high frequency antigen in a U-negative patient.

Author

Revoltar M, Clarke L, Bruce H, Liew YW, and Lopez GH

Subjects

Humans, Male, Adult, Autoantibodies blood, Autoantibodies immunology

Published

2024

4. Impact of transcription factors KLF1 and GATA1 on red blood cell antigen expression: a review.

Author

Lopez GH, Sarri ME, Flower RL, and Hyland CA

Subjects

Humans, Lutheran Blood-Group System genetics, Gene Expression Regulation, Erythropoiesis genetics, Kruppel-Like Transcription Factors genetics, GATA1 Transcription Factor genetics, Erythrocytes metabolism, Erythrocytes immunology, Blood Group Antigens genetics, Blood Group Antigens immunology

Abstract

KLF transcription factor 1 (KLF1) and GATA binding protein 1 (GATA1) are transcription factors (TFs) that initiate and regulate transcription of the genes involved in erythropoiesis. These TFs possess DNA-binding domains that recognize specific nucleotide sequences in genes, to which they bind and regulate transcription. Variants in the genes that encode either KLF1 or GATA1 can result in a range of hematologic phenotypes-from benign to severe forms of thrombocytopenia and anemia; they can also weaken the expression of blood group antigens. The Lutheran (LU) blood group system is susceptible to TF gene variations, particularly KLF1 variants. Individuals heterozygous for KLF1 gene variants show reduced Lutheran antigens on red blood cells that are not usually detected by routine hemagglutination methods. This reduced antigen expression is referred to as the In(Lu) phenotype. For accurate blood typing, it is important to distinguish between the In(Lu) phenotype, which has very weak antigen expression, and the true Lu null phenotype, which has no antigen expression. The International Society of Blood Transfusion blood group allele database registers KLF1 and GATA1 variants associated with modified Lutheran expression. Here, we review KLF1 and recent novel gene variants defined through investigating blood group phenotype and genotype discrepancies or, for one report, investigating cases with unexplained chronic anemia. In addition, we include a review of the GATA1 TF, including a case report describing the second GATA1 variant associated with a serologic Lu(a-b-) phenotype. Finally, we review both past and recent reports on variations in the DNA sequence motifs on the blood group genes that disrupt the binding of the GATA1 TF and either remove or reduce erythroid antigen expression. This review highlights the diversity and complexity of the transcription process itself and the need to consider these factors as an added component for accurate blood group phenotyping., (© 2024 Genghis H. Lopez et al., published by Sciendo.)

Published

2024

5. A Bioinformatically Initiated Approach to Evaluate GATA1 Regulatory Regions in Samples with Weak D, Del, or D- Phenotypes Despite Normal RHD Exons.

Author

McGowan EC, Wu PC, Hellberg Å, Lopez GH, Hyland CA, and Olsson ML

Abstract

Introduction: With over 360 blood group antigens in systems recognized, there are antigens, such as RhD, which demonstrate a quantitative reduction in antigen expression due to nucleotide variants in the non-coding region of the gene that result in aberrant splicing or a regulatory mechanism. This study aimed to evaluate bioinformatically predicted GATA1-binding regulatory motifs in the RHD gene for samples presenting with weak or apparently negative RhD antigen expression but showing normal RHD exons., Methods: Publicly available open chromatin region data were overlayed with GATA1 motif candidates in RHD . Genomic DNA from weak D, Del or D- samples with normal RHD exons ( n = 13) was used to confirm RHD zygosity by quantitative PCR. Then, RHD promoter, intron 1, and intron 2 regions were amplified for Sanger sequencing to detect potential disruptions in the GATA1 motif candidates. Electrophoretic mobility shift assay (EMSA) was performed to assess GATA1-binding. Luciferase assays were used to assess transcriptional activity., Results: Bioinformatic analysis identified five of six GATA1 motif candidates in the promoter, intron 1 and intron 2 for investigation in the samples. Luciferase assays showed an enhancement in transcription for GATA1 motifs in intron 1 and for intron 2 only when the R 2 haplotype variant (rs675072G>A) was present. GATA1 motifs were intact in 12 of 13 samples. For one sample with a Del phenotype, a novel RHD c.1-110A>C variant disrupted the GATA1 motif in the promoter which was supported by a lack of a GATA1 supershift in the EMSA and 73% transcriptional activity in the luciferase assay. Two samples were D+/D- chimeras., Conclusion: The bioinformatic predictions enabled the identification of a novel DEL allele, RHD c.1-110A>C, which disrupted the GATA1 motif in the proximal promoter. Although the majority of the samples investigated here remain unexplained, we provide GATA1 targets which may benefit future RHD regulatory investigations., Competing Interests: M.L.O. declares no actual conflict of interest in relation to this study but in accordance with the journal’s conflict of interest policy, the following is reported: M.L.O. is an inventor of patents on Vel blood group genotyping and own 50% of the shares in BLUsang AB, an incorporated consulting firm that receives royalties for said patents. All other authors state no conflict of interest., (© 2024 The Author(s). Published by S. Karger AG, Basel.)

Published

2024

6. Recurrent pregnancy loss in a patient with anti-Rh17.

Author

Moiz B, Salman M, Rasheed S, Qudus R, Millard G, Hyland CA, Flower RL, Wilson B, Turner R, Lopez GH, and Liew YW

Subjects

Pregnancy, Humans, Female, Rh-Hr Blood-Group System genetics, DNA Copy Number Variations, Genotype, Phenotype, Alleles, Blood Group Antigens genetics, Abortion, Habitual genetics

Abstract

Background: Rh is one of the most important blood group systems in transfusion medicine. The two homologous genes RHD and RHCE are located on chromosome 1p36.11 and encode for RhD and RhCE proteins, respectively. Complex genetic polymorphisms result in a variety of antigenic expression of D, C, E, c, and e. Here, we describe a case of a young female with D-- who developed anti-Rh17 secondary to blood transfusion and had signs of haemolytic disease of the fetus and fetal death in five consecutive pregnancies., Case Description: EDTA-whole blood samples were collected from the patient, husband and eight siblings for blood grouping, phenotyping, and red cell antibody screening. Extracted DNA was genotyped by SNP-microarray and massively parallel sequencing (MPS) with targeted blood group exome sequencing. Copy number variation analysis was performed to identify structural variants in the RHD and RHCE. Routine phenotyping showed all family members were D+. The patient's red blood cells were C-E-c-e-, Rh17- and Rh46- and had anti-Rh17 and anti-e antibodies. MPS showed the patient carried a wildtype RHD sequence and homozygous for RHCE (1)-D (2-9)-CE (10) hybrid gene predicted to express a D-- phenotype., Conclusions: Our patient had a rare D-- phenotype and confirmed to have RHCE/RHD hybrid gene with replacement of 2-9 exons of RHCE by RHD sequences. Unfortunately, our patient developed anti-Rh17 and anti-e antibodies due to blood transfusion and suffered fetal demise in her very first pregnancy. The adverse outcomes could have been prevented by active prenatal management., (© 2023 British Blood Transfusion Society.)

Published

2024

7. Feasibility for non-invasive prenatal fetal blood group and platelet genotyping by massively parallel sequencing: A single test system for multiple atypical red cell, platelet and quality control markers.

Author

McGowan EC, O'Brien H, Sarri ME, Lopez GH, Daly JJ, Flower RL, Gardener GJ, and Hyland CA

Subjects

Pregnancy, Humans, Female, Fetal Blood, Genotype, Feasibility Studies, Prenatal Diagnosis methods, DNA, High-Throughput Nucleotide Sequencing methods, Blood Group Antigens genetics, Antigens, Human Platelet

Abstract

Non-invasive prenatal tests (NIPT) to predict fetal red cell or platelet antigen status for alloimmunised women are provided for select antigens. This study reports on massively parallel sequencing (MPS) using a red cell and platelet probe panel targeting multiple nucleotide variants, plus individual identification single nucleotide polymorphisms (IISNPs). Maternal blood samples were provided from 33 alloimmunised cases, including seven with two red cell antibodies. Cell-free and genomic DNA was sequenced using targeted MPS and bioinformatically analysed using low-frequency variant detection. The resulting maternal genomic DNA allele frequency was subtracted from the cell-free DNA counterpart. Outcomes were matched against validated phenotyping/genotyping methods, where available. A 2.5% subtractive allele frequency threshold was set after comparing MPS predictions for K, RhC/c, RhE/e and Fy a /Fy b against expected outcomes. This threshold was used for subsequent predictions, including HPA-15a, Jk a /Jk b , Kp a /Kp b and Lu a . MPS outcomes were 97.2% concordant with validated methods; one RhC case was discordantly negative and lacked IISNPs. IISNPs were informative for 30/33 cases as controls. NIPT MPS is feasible for fetal blood group genotyping and covers multiple blood groups and control targets in a single test. Noting caution for the Rh system, this has the potential to provide a personalised service for alloimmunised women., (© 2023 The Authors. British Journal of Haematology published by British Society for Haematology and John Wiley & Sons Ltd.)

Published

2024

8. Fatal haemolytic transfusion reaction due to anti-En a and identification of a novel GYPA c.295delG variant in a Thai family.

Author

Suwanwootichai P, Lopez GH, Emthip M, Wilson B, Millard GM, Onpuns S, Laemsri K, Bejrachandra S, and Liew YW

Subjects

Humans, DNA, Isoantibodies, MNSs Blood-Group System genetics, Thailand, Glycophorins genetics, Transfusion Reaction genetics

Abstract

Background and Objectives: High-frequency antigen En a (MNS 28) is expressed on glycophorin A (GPA). En(a-) individuals can form anti-En a when exposed to GPA. A Thai patient formed an antibody that reacted against all reagent red blood cells (RBCs). The patient received incompatible blood resulting in a fatal haemolytic transfusion reaction (HTR). This study aimed to characterize the antibody detected in the patient and investigate the cause of HTR., Materials and Methods: Blood samples from the patient and three of his family members were investigated. Massively parallel sequencing (MPS) and DNA-microarray were used for genotyping. Standard haemagglutination techniques were used for phenotyping and antibody investigations., Results: DNA sequencing showed the patient was homozygous for GYPA*M c.295delG (p.Val99Ter) predicting En(a-). Three family members were heterozygous for GYPA c.295delG. MPS and DNA-microarray predicted the patient was N- discordant with the N+ RBC phenotype. The patient's plasma was positive with enzyme/chemical-treated reagent RBCs but failed to react with En(a-) and M k M k RBCs., Conclusion: The GYPA c.295delG variant prevented GPA expression on RBCs resulting in En(a-) phenotype. The N+ phenotype result was probably due to the anti-N typing reagent detecting 'N' (MNS30) on GPB. The patient's alloantibody has anti-En a specificity., (© 2022 International Society of Blood Transfusion.)

Published

2022

9. Hemolytic disease of the fetus and newborn caused by anti-s D antibody in a GP.Mur/Mur Thai mother and review of the prevalence of s D in Thai blood donors.

Author

Lopez GH, Emthip M, Suwanwootichai P, Millard GM, Wilson B, Onpuns S, Laemsri K, Chiewsilp P, Flower RL, Hyland CA, and Liew YW

Subjects

Blood Donors, Female, Fetus, Glycophorins genetics, Humans, Infant, Newborn, Mothers, Peptide Hydrolases genetics, Phenotype, Pregnancy, Prevalence, Thailand epidemiology, Erythroblastosis, Fetal epidemiology, MNSs Blood-Group System genetics

Abstract

Background: Low-prevalence antigen s D (MNS23) is encoded by GYPB c.173C > G. Hemolytic disease of the fetus and newborn (HDFN) due to anti-s D is rare. A mother delivered a newborn whose red blood cells (RBCs) were DAT-positive and was later diagnosed with HDFN. Serum from the mother was incompatible with the father's RBCs and was used to screen 184 Thai blood donors. This study aimed to investigate the cause of HDFN in a Thai family and determine the prevalence of s D in Thai blood donors., Materials and Methods: Three family members and four blood donors were investigated in the study. Massively Parallel Sequencing (MPS) was used for genotyping. Standard hemagglutination techniques were used in titration studies, phenotyping, and enzyme/chemical studies. Anti-s, anti-Mi a , anti-JENU, and anti-s D reagents were used in serological investigations., Results: The mother was GYP*Mur/Mur. The father and the four donors were GYPB*s/s D predicting S - s + s D +. The baby was GYP*Mur/sD and his RBCs were Mi a +, s +  w with anti-s (P3BER) and JENU+ w . RBCs from two GYPB*s D -positive blood donors reacted with anti-s D (Dreyer). Proteolytic enzyme α-chymotrypsin-treated s D + cells did not react with anti-s D (Wat) produced by the GP.Mur/Mur mother but reacted with the original anti-s D (Dreyer)., Discussion: This is the first report of HDFN due to anti-s D in the Asian population. The genotype frequency for GYPB*s D in a selected Thai blood donor population is 2.2% (4/184). Anti-s D should be considered in mothers with Southeast Asian or East Asian background when antibody identification is unresolved in pregnancies affected by HDFN., (© 2022 The Authors. Transfusion published by Wiley Periodicals LLC on behalf of AABB.)

Published

2022

10. A new high-prevalence LW antigen detected by an antibody in an Indigenous Australian homozygous for LW*A c.309C>A variant.

Author

Lopez GH, Wilson B, Millard GM, Cawthorne TL, Grey DE, Fong EA, Flower RL, Hyland CA, and Liew YW

Subjects

Adult, Australia epidemiology, Female, Hemagglutination, Humans, Prevalence, Rh-Hr Blood-Group System genetics, Blood Group Antigens genetics, Isoantibodies

Abstract

Background and Objectives: The LW gene encodes the LW glycoprotein that carries the antigens of the LW blood group system. LW antigens are distinct from D antigen, however, they are phenotypically related and anti-LW antibodies are often mistaken as anti-D. An antibody was detected in an Australian patient of Aboriginal descent who consistently typed as LW(a+b-). This study aimed to describe the antibody recognizing a high-prevalence antigen on the LW glycoprotein., Study Design and Methods: Samples from the patient and her four siblings were investigated. DNA was genotyped by single nucleotide polymorphism (SNP)-microarray and massively parallel sequencing (MPS) platforms. Red blood cells (RBCs) were phenotyped using standard haemagglutination techniques. Antibody investigations were performed using a panel of phenotyped RBCs from adults and cord blood cells., Results: SNP-microarray and MPS genotyped all family members as LW*A/A, (c.299A), predicting LW(a+b-). In addition, a novel LW*A c.309C>A single nucleotide variant was detected in all family members. The patient and one of her siblings (M4) were LW c.309C>A homozygous. Antibody from the patient reacted positive to all reagent panel RBCs and cord blood cells but negative with RBCs from LW(a-b-), Rh null and sibling M4. Antibody failed to react with RBCs treated with dithiothreitol., Conclusion: Antibody detected in the patient recognized a novel high-prevalence antigen, LWEM, in the LW blood group system. LWEM-negative patients who developed anti-LWEM can be safely transfused with D+ RBCs, however, D- is preferred. Accurate antibody identification can help better manage allocation of blood products especially when D- RBCs are in short supply., (© 2022 International Society of Blood Transfusion.)

Published

2022

11. Frequency of Mi a (MNS7) and Classification of Mi a -Positive Hybrid Glycophorins in an Australian Blood Donor Population.

Author

Lopez GH, Wilson B, Turner RM, Millard GM, Fraser NS, Roots NM, Liew YW, Hyland CA, and Flower RL

Abstract

Background: MNS blood group system genes GYPA and GYPB share a high degree of sequence homology and gene structure. Homologous exchanges between GYPA and GYPB form hybrid genes encoding hybrid glycophorins GP(A-B-A) and GP(B-A-B). Over 20 hybrid glycophorins have been characterised. Each has a distinct phenotype defined by the profile of antigens expressed including Mi a . Seven hybrid glycophorins carry Mi a and have been reported in Caucasian and Asian population groups. In Australia, the population is diverse; however, the prevalence of hybrid glycophorins in the population has never been determined. The aims of this study were to determine the frequency of Mi a and to classify Mi a -positive hybrid glycophorins in an Australian blood donor population., Method: Blood samples from 5,098 Australian blood donors were randomly selected and screened for Mi a using anti-Mi a monoclonal antibody (CBC-172) by standard haemagglutination technique. Mi a -positive red blood cells (RBCs) were further characterised using a panel of phenotyping reagents. Genotyping by high-resolution melting analysis and DNA sequencing were used to confirm serology., Result: RBCs from 11/5,098 samples were Mi a -positive, representing a frequency of 0.22%. Serological and molecular typing identified four types of Mi a -positive hybrid glycophorins: GP.Hut ( n = 2), GP.Vw ( n = 3), GP.Mur ( n = 5), and 1 GP.Bun ( n = 1). GP.Mur was the most common., Conclusion: This is the first comprehensive study on the frequency of Mi a and types of hybrid glycophorins present in an Australian blood donor population. The demographics of Australia are diverse and ever-changing. Knowing the blood group profile in a population is essential to manage transfusion needs., Competing Interests: The authors have no conflicts of interest to disclose., (Copyright © 2019 by S. Karger AG, Basel.)

Published

2020

12. Modified expression of the KEL2 (k) blood group antigen attributed to p.Leu196Val amino acid change three residues from the K/k antigen polymorphism site: implications for donor screening.

Author

Millard GM, Lopez GH, Turner EM, Lizarazu ME, Roots NM, Liew YW, Flower RL, and Hyland CA

Subjects

Antigens, Bacterial chemistry, Antigens, Bacterial genetics, Antigens, Surface chemistry, Antigens, Surface genetics, Blood Donors statistics & numerical data, Erythrocytes immunology, Erythrocytes metabolism, Female, Genotype, Humans, Phenotype, Antigens, Bacterial immunology, Antigens, Surface immunology, Blood Group Antigens immunology, Donor Selection methods

Published

2019

13. Genotyping analysis of MNS blood group GP(B-A-B) hybrid glycophorins in the Chinese Southern Han population using a high-resolution melting assay.

Author

Wei L, Lopez GH, Zhang Y, Wen J, Wang Z, Fu Y, Hyland CA, Flower RL, Luo G, and Ji Y

Subjects

Asian People, Genotype, Genotyping Techniques, Glycophorins genetics, Heterozygote, Homozygote, Humans, Phenotype, Polymorphism, Single Nucleotide genetics, Sequence Analysis, DNA, MNSs Blood-Group System genetics

Abstract

Background: MNS hybrid GP(B-A-B) glycophorins are more commonly found in Southeast Asians and alloantibodies to antigens they carry are clinically significant. Detection of hybrid glycophorins by serologic techniques is limited due to lack of commercial reagents. In this study, a genotyping method for GP(B-A-B) hybrid glycophorins based on high-resolution melting (HRM) analysis was applied for genotyping analysis in the Chinese Southern Han population., Study Design and Methods: DNA samples from 3104 Chinese Southern Han blood donors were collected. GYP(B-A-B) genotypes were analyzed by HRM assay. Parts of samples (n = 106) were also tested by multiplex ligation-dependent probe amplification (MLPA) assay. Direct sequencing was conducted in samples with variant melting curve profiles., Results: A total of five GYP(B-A-B) genotypes (201/3104, 6.5%) were identified, which were GYP*Mur heterozygote (n = 194), GYP*Mur homozygote (n = 3), GYP*Bun heterozygote (n = 2), GYP*HF heterozygote (n = 1), and a novel GYP(B-A-B) hybrid allele (n = 1). Genotyping results for GYP*Mur and wild-type GYPB samples obtained by HRM were consistent with MLPA, while GYP*Bun and GYP*HF heterozygote identified by HRM could only be identified to have one copy of 5' inactive splice site of GYPB Pseudoexon 3 by MLPA. In addition, 10 single-nucleotide polymorphisms (SNPs) including four known and six novel SNPs were identified in 31 samples. One sample was identified carrying both GYP*Mur and GYP*Sch alleles., Conclusion: The HRM assay could distinguish the GYP(B-A-B) hybrid alleles successfully. Polymorphisms identified within the GYPB gene should be taken into consideration when developing GYP(B-A-B) genotyping kits for the Chinese population., (© 2018 AABB.)

Published

2018

14. A DEL phenotype attributed to RHD Exon 9 sequence deletion: slipped-strand mispairing and blood group polymorphisms.

Author

Lopez GH, Turner RM, McGowan EC, Schoeman EM, Scott SA, O'Brien H, Millard GM, Roulis EV, Allen AJ, Liew YW, Flower RL, and Hyland CA

Subjects

Humans, Taiwan, Base Sequence, Exons, Polymorphism, Genetic, Rh-Hr Blood-Group System genetics, Sequence Deletion

Abstract

Background: The RhD blood group antigen is extremely polymorphic and the DEL phenotype represents one such class of polymorphisms. The DEL phenotype prevalent in East Asian populations arises from a synonymous substitution defined as RHD*1227A. However, initially, based on genomic and cDNA studies, the genetic basis for a DEL phenotype in Taiwan was attributed to a deletion of RHD Exon 9 that was never verified at the genomic level by any other independent group. Here we investigate the genetic basis for a Caucasian donor with a DEL partial D phenotype and compare the genomic findings to those initial molecular studies., Study Design and Methods: The 3'-region of the RHD gene was amplified by long-range polymerase chain reaction (PCR) for massively parallel sequencing. Primers were designed to encompass a deletion, flanking Exon 9, by standard PCR for Sanger sequencing. Targeted sequencing of exons and flanking introns was also performed., Results: Genomic DNA exhibited a 1012-bp deletion spanning from Intron 8, across Exon 9 into Intron 9. The deletion breakpoints occurred between two 25-bp repeat motifs flanking Exon 9 such that one repeat sequence remained., Conclusion: Deletion mutations bordered by repeat sequences are a hallmark of slipped-strand mispairing (SSM) event. We propose this genetic mechanism generated the germline deletion in the Caucasian donor. Extensive studies show that the RHD*1227A is the most prevalent DEL allele in East Asian populations and may have confounded the initial molecular studies. Review of the literature revealed that the SSM model explains some of the extreme polymorphisms observed in the clinically significant RhD blood group antigen., (© 2017 AABB.)

Published

2018

15. Targeted exome sequencing defines novel and rare variants in complex blood group serology cases for a red blood cell reference laboratory setting.

Author

Schoeman EM, Roulis EV, Liew YW, Martin JR, Powley T, Wilson B, Millard GM, McGowan EC, Lopez GH, O'Brien H, Condon JA, Flower RL, and Hyland CA

Subjects

Humans, Alleles, Blood Group Antigens genetics, Blood Grouping and Crossmatching methods, Erythrocytes, Exome, High-Throughput Nucleotide Sequencing, Polymorphism, Single Nucleotide

Abstract

Background: We previously demonstrated that targeted exome sequencing accurately defined blood group genotypes for reference panel samples characterized by serology and single-nucleotide polymorphism (SNP) genotyping. Here we investigate the application of this approach to resolve problematic serology and SNP-typing cases., Study Design and Methods: The TruSight One sequencing panel and MiSeq platform was used for sequencing. CLC Genomics Workbench software was used for data analysis of the blood group genes implicated in the serology and SNP-typing problem. Sequence variants were compared to public databases listing blood group alleles. The effect of predicted amino acid changes on protein function for novel alleles was assessed using SIFT and PolyPhen-2., Results: Among 29 unresolved samples, sequencing defined SNPs in blood group genes consistent with serologic observation: 22 samples exhibited SNPs associated with varied but known blood group alleles and one sample exhibited a chimeric RH genotype. Three samples showed novel variants in the CROM, LAN, and RH systems, respectively, predicting respective amino acid changes with possible deleterious impact. Two samples harbored rare variants in the RH and FY systems, respectively, not previously associated with a blood group allele or phenotype. A final sample comprised a rare variant within the KLF1 transcription factor gene that may modulate DNA-binding activity., Conclusion: Targeted exome sequencing resolved complex serology problems and defined both novel blood group alleles (CD55:c.203G>A, ABCB6:c.1118_1124delCGGATCG, ABCB6:c.1656-1G>A, and RHD:c.452G>A) and rare variants on blood group alleles associated with altered phenotypes. This study illustrates the utility of exome sequencing, in conjunction with serology, as an alternative approach to resolve complex cases., (© 2017 AABB.)

Published

2018

16. Non-invasive fetal RHD genotyping for RhD negative women stratified into RHD gene deletion or variant groups: comparative accuracy using two blood collection tube types.

Author

Hyland CA, Millard GM, O'Brien H, Schoeman EM, Lopez GH, McGowan EC, Tremellen A, Puddephatt R, Gaerty K, Flower RL, Hyett JA, and Gardener GJ

Subjects

Blood Specimen Collection, Cohort Studies, Exons genetics, Female, Fetal Diseases blood, Fetal Diseases genetics, Gene Deletion, Genotype, Haplotypes, Humans, Pregnancy, Rho(D) Immune Globulin, Sequence Deletion, Fetal Diseases diagnosis, Prenatal Diagnosis methods, Rh-Hr Blood-Group System genetics

Abstract

Non-invasive fetal RHD genotyping in Australia to reduce anti-D usage will need to accommodate both prolonged sample transport times and a diverse population demographic harbouring a range of RHD blood group gene variants. We compared RHD genotyping accuracy using two blood sample collection tube types for RhD negative women stratified into deleted RHD gene haplotype and RHD gene variant cohorts. Maternal blood samples were collected into EDTA and cell-free (cf)DNA stabilising (BCT) tubes from two sites, one interstate. Automated DNA extraction and polymerase chain reaction (PCR) were used to amplify RHD exons 5 and 10 and CCR5. Automated analysis flagged maternal RHD variants, which were classified by genotyping. Time between sample collection and processing ranged from 2.9 to 187.5 hours. cfDNA levels increased with time for EDTA (range 0.03-138 ng/μL) but not BCT samples (0.01-3.24 ng/μL). For the 'deleted' cohort (n=647) all fetal RHD genotyping outcomes were concordant, excepting for one unexplained false negative EDTA sample. Matched against cord RhD serology, negative predictive values using BCT and EDTA tubes were 100% and 99.6%, respectively. Positive predictive values were 99.7% for both types. Overall 37.2% of subjects carried an RhD negative baby. The 'variant' cohort (n=15) included one novel RHD and eight hybrid or African pseudogene variants. Review for fetal RHD specific signals, based on one exon, showed three EDTA samples discordant to BCT, attributed to high maternal cfDNA levels arising from prolonged transport times. For the deleted haplotype cohort, fetal RHD genotyping accuracy was comparable for samples collected in EDTA and BCT tubes despite higher cfDNA levels in the EDTA tubes. Capacity to predict fetal RHD genotype for maternal carriers of hybrid or pseudogene RHD variants requires stringent control of cfDNA levels. We conclude that fetal RHD genotyping is feasible in the Australian environment to avoid unnecessary anti-D immunoglobulin prophylaxis., (Copyright © 2017. Published by Elsevier B.V.)

Published

2017

17. Genotyping by sequencing defines independent novel RHD variants for an antenatal patient and a blood donor.

Author

Lopez GH, McGowan EC, Condon JA, Schoeman EM, Millard GM, O'Brien H, Roulis EV, Ochoa-Garay G, Liew YW, Flower RL, and Hyland CA

Subjects

Amino Acid Substitution, Antibodies, Monoclonal immunology, Coombs Test, Exons genetics, Female, Humans, Microarray Analysis, Polymorphism, Single Nucleotide, Pregnancy, Sequence Deletion, Blood Donors, Genotyping Techniques, Rh-Hr Blood-Group System genetics, Sequence Analysis, DNA

Published

2017

18. Anti-D in a mother, hemizygous for the variant RHD*DNB gene, associated with hemolytic disease of the fetus and newborn.

Author

Quantock KM, Lopez GH, Hyland CA, Liew YW, Flower RL, Niemann FJ, and Joyce A

Subjects

ABO Blood-Group System blood, DNA Mutational Analysis, Erythroblastosis, Fetal pathology, Erythroblastosis, Fetal therapy, Female, Fetal Diseases, Fetus, Genotype, Humans, Infant, Newborn, Mothers, Polymorphism, Single Nucleotide, Pregnancy, Rh-Hr Blood-Group System blood, Erythroblastosis, Fetal blood, Rh Isoimmunization complications, Rho(D) Immune Globulin adverse effects

Abstract

Background: Individuals with the partial D phenotype when exposed to D+ red blood cells (RBCs) carrying the epitopes they lack may develop anti-D specific for the missing epitopes. DNB is the most common partial D in Caucasians and the clinical significance for anti-D in these individuals is unknown., Study Design and Methods: This article describes the serologic genotyping results and clinical manifestations in two group D+ babies of a mother presenting as group O, D+ with alloanti-D., Results: The mother was hemizygous for RHD*DNB gene and sequencing confirmed a single-nucleotide change at c.1063G>A. One baby (group A, D+) displayed bilirubinemia at birth with a normal hemoglobin level. Anti-A and anti-D were eluted from the RBCs. For the next ongoing pregnancy, the anti-D titer increased from 32 to 256. On delivery the baby typed group O and anti-D was eluted from the RBCs. This baby at birth exhibited anemia, reticulocytosis, and hyperbilirubinemia requiring intensive phototherapy treatment from Day 0 to Day 9 after birth and was discharged on Day 13. Intravenous immunoglobulin was also administered. Both babies were heterozygous for RHD and RHD*DNB., Conclusion: The anti-D produced by this woman with partial D DNB resulted in a case of hemolytic disease of the fetus and newborn (HDFN) requiring intensive treatment in the perinatal period. Anti-D formed by women with the partial D DNB phenotype has the potential to cause HDFN where the fetus is D+. Women carrying RHD*DNB should be offered appropriate prophylactic anti-D and be transfused with D- RBCs if not already alloimmunized., (© 2017 AABB.)

Published

2017

19. Diverse and novel RHD variants in Australian blood donors with a weak D phenotype: implication for transfusion management.

Author

McGowan EC, Lopez GH, Knauth CM, Liew YW, Condon JA, Ramadi L, Parsons K, Turner EM, Flower RL, and Hyland CA

Subjects

Alleles, Australia, Base Sequence, Blood Transfusion, DNA chemistry, DNA isolation & purification, DNA metabolism, Epitopes immunology, Epitopes metabolism, Exons, Gene Frequency, Genotype, Humans, Isoantibodies blood, Phenotype, Polymorphism, Single Nucleotide, Rho(D) Immune Globulin blood, Sequence Analysis, DNA, Serologic Tests, Blood Donors statistics & numerical data, Rh-Hr Blood-Group System genetics

Abstract

Background and Objectives: Variant RHD genes associated with the weak D phenotype can result in complete or partial D-epitope expression on the red cell. This study examines the genetic classification in Australian blood donors with a weak D phenotype and correlates RHD variants associated with the weak D phenotype against D-epitope profile., Materials and Methods: Following automated and manual serology, blood samples from donors reported as 'weak D' (n = 100) were RHD genotyped by a commercial SNP-typing platform and Sanger sequencing. Two commercial anti-D antibody kits were used for extended serological testing for D-epitope profiles., Results: Three samples had wild-type RHD exonic sequences, and 97 samples had RHD variants. RHD*weak D type 1, RHD*weak D type 2 or RHD*weak D type 3 was detected in 75 donors. The remaining 22 samples exhibited 17 different RHD variants. One donor exhibited a novel RHD*c.939+3A>C lacking one D-epitope. Weak D types 1·1, 5, 15, 17 and 90 showed a partial D-epitope profile., Conclusion: The array of RHD variants detected in this study indicated diversity in the Australian donor population that needs to be accommodated for in future genotyping strategies., (© 2017 International Society of Blood Transfusion.)

Published

2017

20. Evaluation of targeted exome sequencing for 28 protein-based blood group systems, including the homologous gene systems, for blood group genotyping.

Author

Schoeman EM, Lopez GH, McGowan EC, Millard GM, O'Brien H, Roulis EV, Liew YW, Martin JR, McGrath KA, Powley T, Flower RL, and Hyland CA

Subjects

Female, Humans, Male, Genome, Human, Genotyping Techniques methods, Polymorphism, Single Nucleotide, Rh-Hr Blood-Group System genetics

Abstract

Background: Blood group single nucleotide polymorphism genotyping probes for a limited range of polymorphisms. This study investigated whether massively parallel sequencing (also known as next-generation sequencing), with a targeted exome strategy, provides an extended blood group genotype and the extent to which massively parallel sequencing correctly genotypes in homologous gene systems, such as RH and MNS., Study Design and Methods: Donor samples (n = 28) that were extensively phenotyped and genotyped using single nucleotide polymorphism typing, were analyzed using the TruSight One Sequencing Panel and MiSeq platform. Genes for 28 protein-based blood group systems, GATA1, and KLF1 were analyzed. Copy number variation analysis was used to characterize complex structural variants in the GYPC and RH systems., Results: The average sequencing depth per target region was 66.2 ± 39.8. Each sample harbored on average 43 ± 9 variants, of which 10 ± 3 were used for genotyping. For the 28 samples, massively parallel sequencing variant sequences correctly matched expected sequences based on single nucleotide polymorphism genotyping data. Copy number variation analysis defined the Rh C/c alleles and complex RHD hybrids. Hybrid RHD*D-CE-D variants were correctly identified, but copy number variation analysis did not confidently distinguish between D and CE exon deletion versus rearrangement., Conclusion: The targeted exome sequencing strategy employed extended the range of blood group genotypes detected compared with single nucleotide polymorphism typing. This single-test format included detection of complex MNS hybrid cases and, with copy number variation analysis, defined RH hybrid genes along with the RHCE*C allele hitherto difficult to resolve by variant detection. The approach is economical compared with whole-genome sequencing and is suitable for a red blood cell reference laboratory setting., (© 2017 AABB.)

Published

2017

21. An alloantibody in a homozygous GYP*Mur individual defines JENU (MNS49), a new high-frequency antigen on glycophorin B.

Author

Lopez GH, Wilson B, Liew YW, Kupatawintu P, Emthip M, Hyland CA, and Flower RL

Subjects

Base Sequence genetics, Erythrocytes metabolism, Humans, Isoantibodies genetics, MNSs Blood-Group System metabolism, Thalassemia genetics, Glycophorins genetics, Isoantibodies immunology

Published

2017

22. Genotyping for Glycophorin GYP(B-A-B) Hybrid Genes Using a Single Nucleotide Polymorphism-Based Algorithm by Matrix-Assisted Laser Desorption/Ionisation, Time-of-Flight Mass Spectrometry.

Author

Wei L, Lopez GH, Ji Y, Condon JA, Irwin DL, Luo G, Hyland CA, and Flower RL

Subjects

Algorithms, Gene Frequency, Humans, Sequence Analysis, DNA, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization methods, Genotyping Techniques methods, Glycophorins genetics, Polymorphism, Single Nucleotide

Abstract

The genetic basis for five GP(B-A-B) MNS system hybrid glycophorin blood group antigens results from rearrangement between the homologous GYPA and GYPB genes. Each hybrid glycophorin displays a characteristic profile of antigens. Currently, no commercial serological reagents are currently available to serologically type for these antigens. The aim of this study was to develop a single nucleotide polymorphism (SNP) mapping genotyping technique to allow characterisation of various GYP(B-A-B) hybrid alleles. Matrix-assisted laser desorption/ionisation time-of-flight (MALDI-TOF) mass spectrometry (MS) assays were designed to genotype five GYP(B-A-B) hybrid alleles. Eight nucleotide positions were targeted and incorporated into the SNP mapping protocol. The allelic frequencies were calculated using peak areas. Sanger sequencing was performed to resolve a GYP*Hop 3' breakpoint. Observed allelic peak area ratios either coincided with the expected ratio or were skewed (above or below) from the expected ratio with switching occurring at and after the expected break point to generate characteristic mass spectral plots for each hybrid. Sequencing showed that the GYP*Hop crossover in the intron 3 region, for this example, was identical to that for GYP*Bun reference sequence. An analytical algorithm using MALDI-TOF MS genotyping platform defined GYPA inserts for five GYP(B-A-B) hybrids. The SNP mapping technique described here demonstrates proof of concept that this technology is viable for genotyping hybrid glycophorins, GYP(A-B-A), GYP(A-B) and GYP(B-A), and addresses the gap in current typing technologies.

Published

2016

23. A D+ blood donor with a novel RHD*D-CE(5-6)-D gene variant exhibits the low-frequency antigen RH23 (D(W) ) characteristic of the partial DVa phenotype.

Author

Lopez GH, McGowan EC, McGrath KA, Abaca-Cleopas ME, Schoeman EM, Millard GM, O'Brien H, Liew YW, Flower RL, and Hyland CA

Subjects

Alleles, Epitopes blood, Epitopes immunology, Erythrocytes metabolism, Exons genetics, Gene Frequency genetics, Humans, Phenotype, Rh-Hr Blood-Group System immunology, Blood Donors statistics & numerical data, Rh-Hr Blood-Group System genetics

Abstract

Background: Blood donors whose red blood cells (RBCs) exhibit a partial RhD phenotype, lacking some D epitopes, present as D+ in routine screening. Such phenotypes can exhibit low-frequency antigens (LFAs) of clinical significance. The aim of this study was to describe the serologic and genetic profile for a blood donor with an apparent D+ phenotype carrying a variant RHD gene where D Exons 5 and 6 are replaced by RHCE Exon (5-6)., Study Design and Methods: Anti-D monoclonal antibodies were used to characterize the presentation of RhD epitopes on the RBCs. RHD exon scanning and DNA sequencing of short- and long-range polymerase chain reaction amplicons were used to determine the RHD structure and sequence. Extended phenotyping for LFAs RH23 (D(W) ) and Rh32 was performed., Results: The donor serology profile was consistent with partial RhD epitope presentation. The donor was hemizygous for an RHD variant allele described as RHD*D-CE(5-6)-D hybrid. The RHCE gene insert is at least 3.868 kb with 5' and 3' breakpoints between IVS4 + 132-c.667 and IVS6 + 1960-IVS6 + 2099, respectively. The sequence for this hybrid was assigned GenBank Accession Number KT099190.2. The RBCs were RH23 (D(W) )+ and Rh32-., Conclusion: A novel RHD*D-CE(5-6)-D hybrid allele encodes a partial RhD epitope and carries the LFA RH23 (D(W) ). This and the epitope profile resemble the partial DVa phenotype. Given that RBCs from this individual lack some RhD epitopes, there is an alloimmunization risk if the donor is exposed to D+ RBCs. Conversely, transfusions of RH23 (D(W) )+ cells to RH23 (D(W) )- recipients also pose an alloimmunization risk., (© 2016 AABB.)

Published

2016

24. GYP*Kip, a novel GYP(B-A-B) hybrid allele, encoding the MNS48 (KIPP) antigen.

Author

Lopez GH, Wei L, Ji Y, Condon JA, Luo G, Hyland CA, and Flower RL

Subjects

Female, Humans, Male, Alleles, Cyclophilins genetics, Glycophorins genetics

Published

2016

25. Identification of six new RHCE variant alleles in individuals of diverse racial origin.

Author

Goldman M, Cemborain A, Cote J, El Hamss R, Flower RL, Garaizar A, Garcia-Sanchez F, Hyland CA, Kalvelage M, Londero D, Lopez GH, Revelli N, Rodriguez-Wilhelmi P, Villa A, and Ochoa-Garay G

Subjects

Genetic Markers, Genotype, Genotyping Techniques, Humans, Phenotype, Sequence Analysis, DNA, Alleles, Black People genetics, Blood Donors, Polymorphism, Genetic, Rh-Hr Blood-Group System genetics, White People genetics

Abstract

Background: The introduction of molecular methods into routine blood typing is prompting the identification of new blood group alleles. Discrepancies between the results of genotyping and serology or chance events uncovered during genotyping prompted additional investigations, which revealed six new RHCE variant alleles., Study Design and Methods: Samples from eight blood donors, two patients (one prenatal), and a patient's relative, all of diverse racial origin, were analyzed by standard serology methods, targeted genotyping arrays, DNA sequencing, and allele-specific polymerase chain reaction., Results: Six new RHCE alleles were identified, namely, RHCE*cE84A, RHCE*ce202G, RHCE*ce307T, RHCE*Ce377G, RHCE*ce697G,712G,733G,744C, and RHCE*Ce733G., Conclusion: While implementation of new assays in commercial genotyping platforms to detect the polymorphisms reported here may not be justified given their apparent rarity, software interpretative algorithms may benefit from the identification of new alleles for a more accurate determination of genotypes and prediction of phenotypes., (© 2015 AABB.)

Published

2016

26. Duffy blood group phenotype-genotype correlations using high-resolution melting analysis PCR and microarray reveal complex cases including a new null FY*A allele: the role for sequencing in genotyping algorithms.

Author

Lopez GH, Morrison J, Condon JA, Wilson B, Martin JR, Liew YW, Flower RL, and Hyland CA

Subjects

Alleles, Base Sequence, Genetic Association Studies, Humans, Molecular Sequence Data, Oligonucleotide Array Sequence Analysis, Phase Transition, Polymerase Chain Reaction, Polymorphism, Single Nucleotide, Sequence Analysis, DNA, Algorithms, Duffy Blood-Group System genetics, Receptors, Cell Surface genetics

Abstract

Background and Objectives: Duffy blood group phenotypes can be predicted by genotyping for single nucleotide polymorphisms (SNPs) responsible for the Fy(a) /Fy(b) polymorphism, for weak Fy(b) antigen, and for the red cell null Fy(a-b-) phenotype. This study correlates Duffy phenotype predictions with serotyping to assess the most reliable procedure for typing., Materials and Methods: Samples, n = 155 (135 donors and 20 patients), were genotyped by high-resolution melt PCR and by microarray. Samples were in three serology groups: 1) Duffy patterns expected n = 79, 2) weak and equivocal Fy(b) patterns n = 29 and 3) Fy(a-b-) n = 47 (one with anti-Fy3 antibody)., Results: Discrepancies were observed for five samples. For two, SNP genotyping predicted weak Fy(b) expression discrepant with Fy(b-) (Group 1 and 3). For three, SNP genotyping predicted Fy(a) , discrepant with Fy(a-b-) (Group 3). DNA sequencing identified silencing mutations in these FY*A alleles. One was a novel FY*A 719delG. One, the sample with the anti-Fy3, was homozygous for a 14-bp deletion (FY*01N.02); a true null., Conclusion: Both the high-resolution melting analysis and SNP microarray assays were concordant and showed genotyping, as well as phenotyping, is essential to ensure 100% accuracy for Duffy blood group assignments. Sequencing is important to resolve phenotype/genotype conflicts which here identified alleles, one novel, that carry silencing mutations. The risk of alloimmunisation may be dependent on this zygosity status., (© 2015 International Society of Blood Transfusion.)

Published

2015

27. Molecular typing for the Indian blood group associated 252G>C single nucleotide polymorphism in a selected cohort of Australian blood donors.

Author

Lopez GH, Mcbean RS, Wilson B, Irwin DL, Liew YW, Hyland CA, and Flower RL

Subjects

Australia, Cohort Studies, Female, Genotyping Techniques, Humans, Male, Alleles, Blood Donors, Gene Frequency, Hyaluronan Receptors genetics, Polymorphism, Single Nucleotide

Abstract

Background: The Indian blood group antigens, In(a) and In(b), are clinically significant in transfusion medicine. However, antisera to type these antigens are difficult to obtain. The In(b) antigen is a high frequency antigen present in all populations, while the frequency of the antithetical In(a) ranges from 0.1% in Caucasians up to 11% in Middle Eastern groups. This antigen polymorphism is encoded by the single nucleotide polymorphism (SNP) 252G>C in CD44. The aim of this study was to establish and compare two genotyping methods to measure the frequency of the IN*A and IN*B alleles in a blood donor cohort., Materials and Methods: Donor blood samples (n=151) were genotyped by a novel real-time polymerase chain reaction (PCR) high-resolution meltcurve (HRM) analysis and a custom matrix-assisted laser desorption/ionisation time-of-flight mass spectrometry (MALDI-TOF MS) assay. Samples with the rare IN*A allele were further investigated by nucleotide sequencing, red cell agglutination, and flow cytometry techniques., Results: In this study group, 149 IN*B homozygous and 2 IN*A/B heterozygous samples were detected with 100% concordance between HRM and MALDI-TOF MS methods. For PCR HRM, amplicon melting alone did not differentiate IN*A and IN*B alleles (class 3 SNP), however, the introduction of an unlabelled probe (UP) increased the resolution of the assay. Sequencing confirmed that the two non-homozygous samples were IN*A/B heterozygous and phenotyping by red cell agglutination, and flow cytometry confirmed both In(a) and In(b) antigens were present as predicted., Discussion: Genotyping permits conservation of rare antisera to predict blood group antigen phenotype. In PCR UP-HRM the IN*A and IN*B alleles were discriminated on the basis of their melting properties. The In(a) frequency in this selected donor population was 1.3%. Application of genotyping methods such as these assists in identifying donors with rare blood group phenotypes of potential clinical significance.

Published

2015

28. A novel FY*A allele with the 265T and 298A SNPs formerly associated exclusively with the FY*B allele and weak Fy(b) antigen expression: implication for genotyping interpretative algorithms.

Author

Lopez GH, Condon JA, Wilson B, Martin JR, Liew YW, Flower RL, and Hyland CA

Subjects

Algorithms, Alleles, Australia, Genotype, Genotyping Techniques methods, Humans, Molecular Sequence Data, Phenotype, White People genetics, Blood Donors, Duffy Blood-Group System genetics, Polymorphism, Single Nucleotide

Abstract

Background and Objectives: An Australian Caucasian blood donor consistently presented a serology profile for the Duffy blood group as Fy(a+b+) with Fy(a) antigen expression weaker than other examples of Fy(a+b+) red cells. Molecular typing studies were performed to investigate the reason for the observed serology profile., Material and Methods: Blood group genotyping was performed using a commercial SNP microarray platform. Sanger sequencing was performed using primer sets to amplify across exons 1 and 2 of the FY gene and using allele-specific primers., Results: The propositus was genotyped as FY*A/B, FY*X heterozygote that predicted the Fy(a+b+(w) ) phenotype. Sequencing identified the 265T and 298A variants on the FY*A allele. This link between FY*A allele and 265T was confirmed by allele-specific PCR., Conclusion: The reduced Fy(a) antigen reactivity is attributed to a FY*A allele-carrying 265T and 298A variants previously defined in combination only with the FY*B allele and associated with weak Fy(b) antigen expression. This novel allele should be considered in genotyping interpretative algorithms for generating a predicted phenotype., (© 2014 International Society of Blood Transfusion.)

Published

2015

29. A standardized immunofluorescence test method with human neutrophil antigen-expressing cell lines to enhance antibody detection.

Author

Lopez GH, Dean MM, Yasui K, Schuller RM, Hirayama F, and Fung YL

Subjects

Animals, Antibodies immunology, Antibody Specificity, Cattle, Cell Line, Humans, Isoantibodies immunology, Isoantigens blood, Isoantigens immunology, Transfection, Antibodies blood, Fluorescent Antibody Technique methods, Isoantibodies blood, Isoantigens biosynthesis, Neutrophils immunology

Abstract

There is an international need for a large-scale human neutrophils antigen (HNA) antibody screening platform to minimize the risk of antibody-mediated transfusion-related acute lung injury. However, sourcing a substantial, reliable source of HNA, as well as the scarcity of well-characterized HNA antisera for validating new screening platforms, remain as major obstacles. This short communication presents an improved protocol for the effective use of HNA-expressing KY cells as a screening platform using eight well-characterized HNA antisera of a single defined specificity., (© 2011 The Author(s). Vox Sanguinis © 2011 International Society of Blood Transfusion.)

Published

2012

30. PCR monitoring for tetracycline resistance genes in subgingival plaque following site-specific periodontal therapy. A preliminary report.

Author

Manch-Citron JN, Lopez GH, Dey A, Rapley JW, MacNeill SR, and Cobb CM

Subjects

Adult, Base Sequence, DNA Probes, DNA, Bacterial genetics, Dental Plaque drug therapy, Dental Plaque microbiology, Drug Delivery Systems, Female, Gingiva, Humans, Male, Molecular Sequence Data, Periodontitis drug therapy, Periodontitis microbiology, Polymerase Chain Reaction statistics & numerical data, Sequence Analysis, DNA, Time Factors, Cellulose antagonists & inhibitors, Dental Plaque genetics, Genes, Bacterial genetics, Periodontitis genetics, Polymerase Chain Reaction methods, Tetracycline antagonists & inhibitors, Tetracycline Resistance genetics

Abstract

Background: The selection of antibiotic resistance genes during antibiotic therapy is a critical problem complicated by the transmission of resistance genes to previously sensitive strains via conjugative plasmids and transposons and by the transfer of resistance genes between gram-positive and gram-negative bacteria. The purpose of this investigation was to monitor the presence of selected tetracycline resistance genes in subgingival plaque during site specific tetracycline fiber therapy in 10 patients with adult periodontitis., Method: The polymerase chain reaction (PCR) was used in separate tests for the presence of 3 tetracycline resistance genes (tetM, tetO and tetQ) in DNA purified from subgingival plaque samples. Samples were collected at baseline, i.e., immediately prior to treatment, and at 2 weeks, and 1, 3, and 6 months post-fiber placement. The baseline and 6-month samples were also subjected to DNA hybridization tests for the presence of 8 putative periodontal pathogenic bacteria., Results: PCR analysis for the tetM resistance gene showed little or no change in 5 patients and a decrease in detectability in the remaining 5 patients over the 6 months following tetracycline fiber placement. The results for tetO and tetQ were variable showing either no change in detectability from baseline through the 6-month sampling interval or a slight increase in detectability over time in 4 of the 10 patients. DNA hybridization analysis showed reductions to unmeasurable levels of the putative periodontal pathogenic bacteria in all but 2 of the 10 patients., Conclusions: These results complement earlier studies of tet resistance and demonstrate the efficacy of PCR monitoring for the appearance of specific resistance genes during and after antibiotic therapy.

Published

2000