International Society of Blood Transfusion Working Party on red cell immunogenetics and blood group terminology: Cancun report (2012).

The International Society of Blood Transfusion Working Party on red cell immunogenetics and blood group terminology convened during the International congress in Cancun, July 2012. This report details the newly identified antigens in existing blood group systems and presents three new blood group systems.

Diagnostic accuracy of spot and timed measurements of urinary albumin concentration to determine microalbuminuria in sickle cell disease.

OBJECTIVE: Whereas measurement of albumin:creatinine ratio (ACR) in spot urine samples is indicated for determining microalbuminuria, its performance or that of urinary albumin excretion rate (UAER) in predicting microalbuminuria in sickle cell disease (SCD) is unclear. We therefore tested the diagnostic performance of these measures in spot and timed urine samples in predicting a UAER in 24-hour samples. METHODS: Thirty participants with SCD had spot, two-hour and four-hour, followed by 24-hour urine collections for ACR, urinary albumin concentration (UAC) and UAER determinations. Receiver operating characteristic (ROC) curve analyses were performed. RESULTS: The areas under the ROC curves for microalbuminuria were 0.99 (CI: 0.97, 1.00) for ACR and 0.97 (CI: 0.92, 1.00) for UAC in spot urine samples. For ACR, at the cut-point of 4.13 mg/mmol, there was 100% sensitivity and 82.6% specificity, allowing an 86.2% correct classification. At the cut-point of UAC = 20.9 mg/L, there was 100% sensitivity and 73.9% specificity, allowing a 79.3% correct classification. Corresponding areas for microalbuminuria in two-hour timed samples were 0.99 (CI: 0.95, 1.00) for ACR and 0.96 (CI: 0.89, 1.00) for UAER.For ACR, the cut-point was 4.64 mg/mmol with 83.3% sensitivity and 91.3% specificity, allowing an 89.7% correct classification. Similarly for UAER, at the cut-point of 21.8 µg/min, there was 83.3% sensitivity and 91.3% specificity, allowing 89.7% correct classification. CONCLUSIONS: The diagnostic performance of ACR and UAC in a spot as well as ACR and UAER in two-hour timed urine samples in patients with SCD is excellent. Healthcare professionals can confidently utilize these measures in this patient population.

Molecular background of RH in Bastiaan, the RH:-31,-34 index case, and two novel RHD alleles.

Anti-hr(B) (-RH31) and anti-Hr(B) (-RH34) were found nearly 40 years ago in the serum of a South African woman. The anti-hr(B) was revealed after adsorption with DcE/DcE red blod cells (RCBs). Numerous anti-hr(B), in the absence of anti-Hr(B), have since been identified. We obtained a sample of blood from this index case (Bastiaan) and report the molecular basis of her D+C-E-c+e+/-, V-VS+Hr+hr(S)+hr(B)-Hr(B)- phenotype as well as results of testing her RBCs using currently available regents. We tested a cohort of African Americans to estimate the frequency of the RHCE*ce 48C,733G,1006T allele, and in addition found two novel RHD alleles. Hemagglutination tests and DNA analyses were performed by standard methods. Analyses revealed homozygosity for RHCE*ce 48C,733G,1006T in Bastiaan. RBCs from Bastiaan were strongly agglutinated by three commercial anti-e reagents. Testing RBCs from people homozygous for RHCE*ce 48C,733G,1006T showed that anti-e MS16, MS17, and MS63 were weakly reactive or non reactive, MS21 was strongly reactive, and HIRO38, HIRO41, and HIRO43 were non reactive. Results show that Bastiaan has RHD*DIIIa150C and RHD*DIIIa-CE(4-7)-D. Tests on 605 samples from random African Americans revealed a frequency of 0.036 for RHCE*ce 48C,733G,1006T and revealed two novel alleles: RHD*186T and RHD*DIIIa150C. The Bastiaan phenotype is encoded by RHD*DIIIa150C-RHCE*ce 48C,733G,1006T and RHD*DIIIa-CE(4-7)-D-RHCE*ce 48C,733G,1006T ; thus, this genotype is the gold standard for the hr(B)-Hr(B)-phenotype. The r'(s) complex encodes VS, which explains why most hr(B)-RCBs are VS+.

Molecular basis of the rare gene complex, DIVa(C)-, which encodes four low-prevalence antigens in the Rh blood group system.

BACKGROUND: Over 40 years ago, an unusual Rh phenotype denoted DIVa(C)- was identified in a case of fatal haemolytic disease of the newborn in the third child of Madame Nou. Her RBCs expressed a partial D, weak C and four low-prevalence Rh antigens: Go(a) (RH30), Rh33 (RH33), Riv (RH45) and FPTT (RH50). The purpose of this study was to determine the molecular basis associated with this rare DIVa(C)- complex. MATERIAL AND METHODS: Blood samples were from three donors previously identified as carrying the DIVa(C)- haplotype. Molecular analyses were performed by standard methods. RESULTS: The three donors were heterozygous for RHD and RHD*DIVa.2, and all carried a compound hybrid allele at the RHCE locus. This hybrid RHCE allele contained exons 2 and 3 from RHD*DIVa.2 and exon 5 from RHD [RHCE*CE-DIVa.2(2-3)-CE-D(5)-CE] and is in cis to RHD*DIVa.2. The RHCE allele on the in trans chromosome differs between the donors and is RHCE*cE in donor 1, RHCE*ce (254C, 733G) in donor 2 and RHCE*ce in donor 3. CONCLUSIONS: The RHD*DIVa.2 encodes the Go(a) antigen, whereas the compound hybrid allele most likely encodes Rh33, Riv and FPTT. The weakly expressed C antigen on RBCs with the DIVa(C)- phenotype could be encoded by exons 2 and 3 from RHD*DIVa.2 in the compound hybrid. This is the first report of RHD*DIVa.2 being involved in a hybrid gene at the RHCE locus. As only one example of anti-Riv has been described, our molecular analysis and findings provide a tool by which to predict Riv expression.

The production, serologic evaluation, and epitope mapping of ten murine monoclonal Dombrock antibodies.

The Dombrock (Do) glycoprotein is a glycosylphosphatidylinositol(GPI)-linked membrane protein carrying Dombrock blood group antigens. There are no standardized typing reagents for Do(a) or Do(b). We have developed ten different monoclonal antibodies(MoAbs) that are specific for Dombrock. The objectives of this study were to characterize these MoAbs serologically and determine the epitopes they recognize. MoAbs were generated by standard fusion methods. Mice were immunized with transfected human embryonic kidney 293T cells expressing high levels Do(a) or Do(b). The MoAbs were tested serologically with untreated and enzymatically or chemically modified red blood cells (RBCs).Serologic inhibition studies were performed with synthetic peptides corresponding to Do(a) and Do(b) amino acid sequences.Pepscan epitope analysis was done on an array of immobilized tridecapeptides corresponding to the full-length polypeptide. All ten antibodies were serologically specific for Dombrock. Eight of the antibodies recognized epitopes that were resistant to treatment with ficin, pronase, a-chymotrypsin, and neuraminidase,but sensitive to trypsin and 0.2 M dithiothreitol (DTT). Five have anti-Do(b)-like specificity. The epitope recognized by MIMA-52 was neuraminidase sensitive, and MIMA-127 epitope recognized a DTT-resistant, linear epitope (90)QKNYFRMWQK(99) of the Dombrock polypeptide. MIMA-127 was the only one of the ten Dombrock MoAbs mapped to a specific sequence of the Dombrock glycoprotein; the other nine MoAbs did not provide aspecific peptide binding pattern. The other MoAbs could not be mapped as they most likely recognize nonlinear, conformation-dependent epitopes, as is evident by their sensitivity to reduction of disulfide bonds by DTT. The dependence of some epitopes on antigen glycosylation is also a possibility.

The molecular basis of the LU:7 and LU:-7 phenotypes.

The Lutheran blood group system currently consists of 20 antigens that have been assigned ISBT numbers. Of these, all but LU7 have been associated with one or more nucleotide changes in LU. The purpose of this study was to determine the molecular basis associated with the LU:-7 phenotype. We obtained a stored sample from one proband with this phenotype and sequenced LU. Using genomic DNA, exons 1 through 15, and their flanking intronic regions, of LU were amplified by polymerase-chain reaction, and the products were sequenced. A homozygous novel missense nucleotide change of 1274A>C in exon 10 of LU was observed. This change is predicted to encode Ala at position 425 in place of Glu of the consensus Lu glycoprotein. Based on these results, and an absence of a record of this change in the Single Nucleotide Polymorphism database, Glu425 in the Lu glycoprotein is required for expression of Lu7, and Ala425 is associated with the LU:-7 phenotype. This completes the molecular basis associated with all antigens known to be in the Lutheran blood group system.

Red cells from the original JAL+ proband are also DAK+ and STEM+.

BACKGROUND: The low-prevalence Rh antigen, JAL, was named after the index case, Mr. J. Allen. Based on reactivity of seven multi-specific sera with his RBCs, it was apparent that they express at least one additional low-prevalence antigen. The purpose of this study was to investigate the other low-prevalence antigen(s) on J. Allen's RBCs. METHODS: Blood samples and reagents were from our collections. Hemagglutination and DNA analyses were performed by standard methods. RESULTS: Our DNA analyses confirmed the presence of RHCE*ceS(340T) in J. Allen and revealed the presence of RHCE*ceBI (ce 48C, 712G, 818T, 1132G) and RHD*DOL (509T, 667T). RBCs from J. Allen were agglutinated by anti-JAL, anti-STEM, and anti-DAK. Two of the reactive multi-specific sera reported in the original paper reacted with RBCs from J. Allen, and with RBCs from four other people with RHCE*ceBI, including the original STEM+ index case (P. Stemper) but not with RBCs with the DIIIa, DAK+ phenotype. We conclude that they contain anti-STEM. CONCLUSION: J.Allen's RBCs express the low-prevalence Rh antigens, JAL, V/VS (extremely weakly), STEM, and DAK. The presence of JAL on the variant Rhce, RhceJAL (16Cys, 114Trp, 245Val), STEM on the variant Rhce, RhceBI (16Cys, 238Val, 273Val, 378Val), and DAK on the variant RhD (170Thr, 223Val), encoded by RHD*DOL in trans to RHCE*ceBI is consistent with expression of these antigens. When J. Allen RBCs are used to detect and identify an anti-JAL, it is important to remember that they also express STEM and DAK.

The ISBT 700 series of low-incidence and 901 series of high-incidence blood group antigens.

The International Society of Blood Transfusion Working Party on Terminology for Red Cell Surface Antigens developed a terminology that brought order to the chaos of antigen names. They classified antigens into three categories: systems, collections, and series. This review summarizes the early decisions of the Working Party with an emphasis on the 700 series of low-incidence antigens and 901 series of high-incidence antigens.

Possible suppression of fetal erythropoiesis by the Kell blood group antibody anti-Kp(a).

Antibodies to antigens in the Kell blood group system are usually immunoglobulin G, and, notoriously, anti-K, anti-k, and anti-Kp(a) can cause severe hemolytic transfusion reactions, as well as severe hemolytic disease of the fetus and newborn (HDFN). It has been shown that the titer of anti-K does not correlate with the severity of HDFN because, in addition to immune destruction of red blood cells (RBCs), anti-K causes suppression of erythropoiesis in the fetus, which can result in severe anemia. We report a case involving anti-Kp(a) in which one twin was anemic and the other was not. Standard hemagglutination and polymerase chain reaction (PCR)-based tests were used. At delivery, anti-Kp(a) was identified in serum from the mother and twin A, and in the eluate prepared from the baby's RBCs. PCR-based assays showed twin A (boy) was KEL*841T/C (KEL*03/KEL*04), which is predicted to encode Kp(a+b+). Twin B (girl) was KEL*841C/C (KEL*04/KEL*04), which is predicted to encode Kp(a­b+). We describe the first reported case of probable suppression of erythropoiesis attributable to anti-Kp(a). One twin born to a woman whose serum contained anti-Kp(a) experienced HDFN while the other did not. Based on DNA analysis, the predicted blood type of the affected twin was Kp(a+b+) and that of the unaffected twin was Kp(a­b+). The laboratory findings and clinical course of the affected twin were consistent with suppression of erythropoiesis in addition to immune RBC destruction.

Prevalence of RHD*DOL and RHCE*ce(818T) in two populations.

The alleles RHCE*ceBI (RHCE*ce 48C, 712G, 818T, 1132G) and RHCE*ceSM (RHCE*ce 48C, 712G, 818T) encode the low-prevalence Rh antigen STEM. These alleles frequently travel in cis with RHD*DOL. To estimate the frequency of these alleles, we tested a total of more than 700 samples in two populations. Blood samples were obtained from patients with sickle cell disease and from blood donors of African descent. DNA extractions and analyses were performed by standard methods. In the United States, none of 70 patient samples had the RHCE*818 nucleotide change. Two of 220 donors (frequency of 0.009) were heterozygous for RHCE*818C/T (RHCE*ceBI). One of these samples had RHD/RHD*DOL and the other had RHD/RHD*DOL-2. In these 290 samples, no other RHD*DOL alleles were found. In Brazil, 1 of 244 patients with sickle cell disease (frequency of 0.004) and 1 of 171 donors (frequency of 0.006) were heterozygous for RHCE*818C/T (RHCE*ceBI). Testing of more than 500 additional samples from people of African descent, selected because they had a diverse range of common and variant RHCE alleles, did not reveal a sample with RHD*DOL or RHD/RHD*DOL-2 in the absence of RHCE*ce(818T). Although the numbers are small, our study shows that in the United States, the frequency of RHCE*818T is 0.007 (2 in 290 samples) and in Brazil it is 0.004 (2 in 515 samples). The four RHCE*818T alleles were RHCE*ceBI.

Penile cancer in Jamaicans managed at the University Hospital of the West Indies.

OBJECTIVES: The aim of this study is to determine the prevalence and clinicopathological correlates of penile cancer as well as the clinical outcomes in a sample of Jamaicans managed at the University Hospital of the West Indies (UHWI). METHODS: All available records of patients diagnosed with penile cancer from 1998-2008 at the UHWI were obtained. Patient demographics, circumcision status, sexually transmitted infection status, lesion duration, location and size, and lymph node status were obtained. Histology, differentiation and stage were recorded. Information was obtained regarding treatment and outcome. The current data were compared with a previous report from UHWI in 1959. RESULTS: The records of 22 of 26 patients with penile cancer were available for review. Mean (SD) age of patients was 68 (13) years. Eighteen (86%) patients were uncircumcised Mean tumour size was 5.7 (2.6) cm; 8 (36%) lesions involved the entire penis. Sixteen (73%) lesions had clinically regional disease and 11 (52%) patients had advanced pathological stage. Surgical treatment was performed in 15 (68%) patients. Case fatality was 38%, with median survival following surgical intervention of 38 person-months. The major predictor of death in this series was increasing age (HR = 1.06, 95% CI 0.99, 1.1, p = 0.079). There was an increase in age and clinical stage of the cancer at presentation in the current series; however there was no difference in survival. CONCLUSION: Penile cancer is an uncommon cancer, seen at an advanced stage in Jamaicans. Overall survival is poor and advanced age is a major predictor of death.

Consortium for Blood Group Genes (CBGG): 2009 report.

Consortium for Blood Group Genes is a worldwide organization whose goal is to have a vehicle to interact, establish guidelines, operate a proficiency program, and provide education for laboratories involved in DNA and RNA testing for the prediction of blood group, platelet, and neutrophil antigens. Currently, the consortium operates with representatives from Brazil, Canada, and the United States. Membership is voluntary with the expectation that members actively contribute to discussions involving blood group genetics. This year witnessed a change in the standing committee membership and the institution of a representative for the human platelet antigens group. Looking forward, the consortium sees challenges for the nomenclature of blood group alleles and user-required specifications for laboratory information systems to store genotype information.

RHCE*ceAR encodes a partial c (RH4) antigen.

Thr Rh blood group system is highly complex both in the number of discreet antigens and in the existence of partial antigens, especially D and e. Recently, several partial c antigens have been reported. Here we report findings on an African American man with sickle cell disease whose RBCs typed C+c+ and whose plasma contained anti-c. Hemagglutination tests, DNA extraction, PCR-RFLP, reticulocyte RNA isolation, RT-PCR cDNA analyses, cloning, and sequencing were performed by standard procedures. RBCs from the patient typed C+c+ but his plasma contained alloanti-c. DNA analyses showed the presence of RHCE*Ce in trans to RHCE*ceAR with RHD*D and RHD*Weak D type 4.2.2. The amino acid changes on RhceAR are such that C+c+ patient made alloanti-c. This case shows that RhceAR carries a partial c antigen and illustrates the value of DNA testing as an adjunct to hemagglutination to aid in antibody identification in unusual cases.

The Gerbich blood group system: a review.

Antigens in the Gebrich blood group system are expressed on glycophorin C (GPC) and glycophorin D (GPD), which are both encoded by a single gene, GYPC. The GYPC gene is located on the long arm of chromosome 2, and Gebrich antigens are inherited as autosomal dominant traits. There are 11 antigens in the Gebrich blood group system, six of high prevalence (Ge2, Ge3, Ge4, GEPL [Ge10*], GEAT [Ge11*], GETI [Ge12*]) and five of low prevalence (Wb [Ge5], Ls(a) [Ge6], An(a) [Ge7], Dh(a) [Ge8], GEIS [Ge9]). GPC and GPD interact with protein 4.1R, contributing stability to RBC membrane. Reduced levels of GPC and GPD are associated with hereditary elliptocytosis, and Gebrich antigens act as receptors for the malarial parasite Plasmodium falciparum. Anti-Ge2 and anti-Ge3 have caused hemolytic transfusion reactions, and anti-Ge3 has produced hemolytic disease of the fetus and newborn (HDFN).

The Dombrock blood group system: a review.

The Dombrock blood group system (Do) consists of two antithetical antigens (Do(a) and Do(b)) and five antigens of high prevalence (Gy(a), Hy, Jo(a), DOYA, and DOMR). Do antigens are carried on the Dombrock glycoprotein, which is attached to the RBC membrane via glycosylphosphatidylinositol linkage. The gene (DO, ART4) encoding the Do glycoprotein, located on the short arm of chromosome 12, has been cloned and sequenced, allowing the molecular basis of the various Do phenotypes to be determined. Do(a) and Do(b) have a prevalence that makes them useful as genetic markers; however, the paucity of reliable anti-Do(a) and anti-Do(b) has prevented this potential from being realized. The ease with which these antigens can be predicted by analysis of DNA opens the door for such studies to be carried out. Anti-Do(a) and anti-Do(b) are rarely found as a single specificity, but they have been implicated in causing hemolytic transfusion reactions. This review is a synthesis of our current knowledge of he Dombrock blood group system.

The Cromer blood group system: a review.

The antigens of the Cromer blood group system reside on decay-accelerating factor (DAF), a protein belonging to the regulators of complement activation family. The blood group system consists of 12 high-prevalence and three low-prevalence antigens. The molecular basis for the antigens is known, and with the exception of IFC, each antigen is the product of a single nucleotide change in the DAF gene and has been localized to one of the four complement control protein (CCP) domains on the DAF protein. The RBCs of people with the Cromer null phenotype, Inab, lack DAF but do not appear to demonstrate increased susceptibility to hemolysis. Antibodies to Cromer antigens are rarely encountered, although there is evidence that the antibodies may cause accelerated destruction of transfused RBCs. There is no risk of HDN associated with Cromer system antibodies because the placenta is a rich source of fetally derived DAF, which is thought to adsorb the antibodies.

The efficacy of calcitriol therapy in the management of bone loss and fractures: a qualitative review.

UNLABELLED: Osteoporosis, a skeletal disorder characterized by a reduction in bone strength, increases fracture risk. Primary osteoporosis is usually a result of reduced bone mineral density as a consequence of natural aging. Secondary osteoporosis is usually a result of a disease, such as cystic fibrosis, or medical treatment, such as corticosteroids or cancer treatment. INTRODUCTION: Currently, ten million Americans are osteoporotic and an additional 34 million have the precursor condition, osteopenia. Osteoporosis leads to 1.5 million fractures and 500,000 hospitalizations annually. Osteoporosis-related fractures increase mortality and reduce quality of life. Calcitriol, the active form of vitamin D, regulates intestinal calcium absorption, among other actions. During the past four decades, many clinical trials investigating the effect of calcitriol on bone loss have been performed. METHODS: We conducted a systematic qualitative review of clinical trials that assessed calcitriol for the treatment of osteoporosis and bone loss. In these clinical trials, calcitriol was used as a monotherapy and in combination with other therapeutic bone agents. RESULTS AND CONCLUSION: Studies using calcitriol monotherapy, although not conclusive, found that calcitriol slowed the rate of bone loss in a variety of populations. Calcitriol in combination with other therapeutic bone agents was shown to have additional bone-preserving effects when compared to the use of therapeutic bone agents alone. A common side-effect of calcitriol therapy was hypercalcemia and hypercalciuria, but the degree of hypercalcemia was mild. Recent research found that intermittent dosing can reduce hypercalcemia rates. Calcitriol, alone or in combination with other agents, should be considered for the therapy of osteoporosis.

Consortium for Blood Group Genes (CBGG): 2008 report.

The Consortium for Blood Group Genes is a worldwide organization whose goal is to have a vehicle to interact, establish guidelines, operate a proficiency program, and provide education for laboratories involved in DNA and RNA testing for the prediction of blood group, platelet, and neutrophil antigens.