Summary One of the major factors that have contributed to improving the outcomes of Stem Cell Transplantation is progress made in the field of human leucocyte antigen(s)(HLA). This is evident not only in developing techniques for rapid and accurate tissue typing, but also in the greatly improved understanding of the HLA system and the impact of HLA matching on transplant complications. It is now accepted that high-resolution HLA matching for transplant recipients and unrelated donors is associated with the best clinical outcomes. The most important HLA determinants are the six 'classical' polymorphic HLA loci: HLA-A,-B,-C,-DRB1,-DQB1,-DPB1. For several years, based on the outcome of numerous studies, a 10/10 matched donor (HLA-A,-B,-C,-DRB1,-DQB1) was considered the ideal. The impact of HLA-DPB1 has been less clear, in view of reduced likelihood of patient/donor matching for this locus. More recently, several large studies have questioned the importance of HLA-DQB1 matching on outcome. Based on the findings of recent studies, the current gold standard unrelated donor is believed to be one matched for 8/8 alleles at high resolution i.e. matched for HLA-A,-B,-C,-DRB1, however, in certain circumstances, mismatches may be tolerated and/or permissive.

We report a novel KIR3DL1*072 allele that was found using a sequence-based typing approach.

Sequence-based typing (SBT) is a powerful method of genotyping in highly polymorphic gene systems. In standard SBT methods, both strands of a double-stranded template amplicon are sequenced in separate reactions in order to achieve high quality data across the region of interest. The amount of informative data that is obtained from the second strand sequence is often low, whilst the impact of performing second strand sequencing on costs and throughput are significant. Here we present short template amplicon and multiplex megaprimer-enabled relay (STAMMER) sequencing, a novel simultaneous sequence-based typing methodology that allows the detection of any practical amount of useful sequence from a plurality of distinct polymerase chain reaction products in a single sequencing reaction. In addition to simultaneous bidirectional sequencing, we show how the STAMMER approach can be used to simultaneously sequence a number of regions of interest that are not physically linked within the range of a single sequencing reaction. The efficiencies of this method could impact significantly on the output of SBT laboratories.

Growing inventories of cord blood units have facilitated access to umbilical cord cell transplantation for many patients lacking conventional stem cell donors. They are in principle 'off-the-shelf','fit-for-use', as well as safe and effective therapy products. Cellular enumeration is used as a surrogate of graft potency, and users rely on the rigorous assessment carried out in banks to avoid poor engraftment after thawing (loss of cells or poor function), when the patient's situation is critical. However, in practice, when units are selected, initially on the basis of HLA matching and cell dose assessment, their absolute quality remains uncertain. Unfortunately, quality-related issues (particularly related to viability) are not uncommon in cord blood transplantation. The reasons for potency failures are diverse, but a lack of thorough validation during critical steps of the process and of appropriate use of quality-control tools for timely detection of problematic units are significant contributors. Moreover, incongruence between different sets of standards and regulations, and lack of common quality systems between banks result in a highly heterogeneous international inventory. Therefore, this complicates the matter for the end user of the product. To ameliorate this situation, it is essential to improve quality at each of the critical manufacturing steps wherein potency can be threatened, thereby creating homogeneous inventories of units with excellent quality and quantity.Bone Marrow Transplantation advance online publication, 1 March 2010; doi:10.1038/bmt.2010.7.

Cytomegalovirus (CMV) causes significant morbidity and mortality in patients after haematopoietic stem cell transplantation (HSCT). Due to limitations of current antiviral therapies, alternative approaches, involving transfer of donor-derived CMV-specific CD8(+) T cells, have been considered. Levels of such cells correlating with protection against CMV infection and disease have only been reported in patients expressing HLA-A*0201 and HLA-B*0702. This is despite an increasing number of reports describing cells targeting CMV peptides presented by other human leucocyte antigens (HLAs). Considering several frequent HLA alleles, our findings suggest that HLA-A*2402/pp65 (341-349)- and HLA-B*3501/pp65 (123-131)-specific CD8+ T cells correlate with protection from CMV reactivation at significantly lower cell levels than HLA-A*0101/pp50 (245-253)- and HLAA* 0201/pp65 (495-503)-specific CD8+ T cells, both in HSCT recipients posttransplant and in healthy CMV seropositive volunteers. This may result from a differing efficiency of the responses restricted by the two sets of HLA alleles. These findings add to the knowledge of immunodominance and differences in antigen processing that are coordinated in individuals with different HLA alleles and have direct implications for therapy and monitoring in patients.

Disease stage and recipient/donor human leukocyte antigen (HLA) matching are important determinants of outcome in transplantation using volunteer-unrelated donors (VUD). Matching for HLA-A,-B,-C,-DRB1,-DQB1 is beneficial, whereas the importance of DPB1 matching is more controversial. The impact of HLA matching status may differ dependent on disease stage. We investigated the outcome according to the degree of HLA matching at 6 loci, in 488 recipients of predominantly T-cell depleted bone marrow VUD transplants for leukaemia. Survival was significantly better in 12/12-matched transplants in those with early leukaemia (5 years: 63 versus 41% in 10/10 matched, P=0.006), but not late stage disease. Conversely, within the HLA-mismatched group (</=9/10), there was a significant survival advantage to DPB1 mismatching (5 years: 39 versus 21% in DPB1 matched, P=0.008), particularly in late leukaemia (P=0.01), persisting in multivariate analysis (odds ratio 0.478; 95% confidence interval 0.30, 0.75; P=0.001). These novel findings suggest that the best outcome for patients with early leukaemia, with a 10/10-matched donor, is achieved by matching for DPB1. Conversely, our results suggest that in patients receiving an HLA-mismatched graft, the outcome is significantly better if they are also mismatched for DPB1. We recommend validation of these results in independent datasets.Leukemia advance online publication, 19 November 2009; doi:10.1038/leu.2009.239.

Summary Cytomegalovirus (CMV) causes significant morbidity and mortality in patients after haematopoietic stem cell transplantation (HSCT). Due to limitations of current antiviral therapies, alternative approaches, involving transfer of donor-derived CMV-specific CD8(+) T cells, have been considered. Levels of such cells correlating with protection against CMV infection and disease have only been reported in patients expressing HLA-A*0201 and HLA-B*0702. This is despite an increasing number of reports describing cells targeting CMV peptides presented by other human leucocyte antigens (HLAs). Considering several frequent HLA alleles, our findings suggest that HLA-A*2402/pp65 (341-349)- and HLA-B*3501/pp65 (123-131)-specific CD8(+) T cells correlate with protection from CMV reactivation at significantly lower cell levels than HLA-A*0101/pp50 (245-253)- and HLA-A*0201/pp65 (495-503)-specific CD8(+) T cells, both in HSCT recipients post-transplant and in healthy CMV seropositive volunteers. This may result from a differing efficiency of the responses restricted by the two sets of HLA alleles. These findings add to the knowledge of immunodominance and differences in antigen processing that are coordinated in individuals with different HLA alleles and have direct implications for therapy and monitoring in patients.

Transplantation of cord blood (CB) is increasingly used as therapy for patients whose own marrow is affected by genetic mutations that prevent the development of normal cells of the blood or immune tissues, or for patients whose marrow has been destroyed in the course of treatment for leukaemia and other malignancies. CB is a rich source of haematopoietic stem cells, can be easily harvested and stored in frozen aliquots in a CB bank. The first public CB bank was established in 1993 allowing unrelated CB transplantation to become an option for patients lacking a suitable adult donor. Today, the results of CB transplantation are comparable to those of bone marrow transplants with several important advantages: the graft is available 'off the shelf', thereby reducing the waiting time, and the requirements of human lecucoyte antigen (HLA) matching are less restrictive than those of adult sources. The reduced requirement for HLA matching allows transplants between incompletely matched donors and recipients, thus reducing the size of the inventory required at the national level. This also mitigates the disadvantage encountered by persons of rare HLA genotypes or those who do not belong to populations of North Western European descent. Finally, national CB programmes can easily make available for research individual surplus units not meeting minimal criteria for clinical use.

Background A variety of immune pathways can lead to graft-versus-host disease. A better understanding of the type of immune response causing graft versus host disease in defined clinical hematopoietic stem cell transplant settings is required to inform development of methods for monitoring patients and providing them tailored care. DESIGN AND METHODS: Twenty-five patients were recruited presenting with myeloid malignancies and treated with a reduced intensity conditioning transplant regimen with graft versus host disease prophylaxis comprising in vivo lymphocyte depletion with alemtuzumab and cyclosporin. A prospective study was performed of lymphocyte subset reconstitution in peripheral blood in relation to graft versus host disease incidence. RESULTS: Acute graft versus host disease was associated with significantly higher numbers of natural killer cells and donor-derived effector CD4 T cells (CD45RO(+) CD27(-)) early (day 30) after transplantation (p=0.04 and p=0.02, respectively). This association was evident before the emergence of clinical pathology in six out of seven patients. Although numbers of regulatory CD4 T cells (CD25(high) Foxp3(+)) were similar at day 30 in all patients, a significant deficit in those who developed acute graft versus host disease was apparent relative to effector CD4 T cells (median of 41 effectors per regulatory cell compared to 12 to 1 for patients without graft versus host disease)(p=0.03). By day 180, a functional regulatory CD4 T-cell population had expanded significantly in patients who developed chronic graft-versus-host disease, reversing the imbalance (median of 3 effectors per regulatory cell compared to 9.6 to 1 for patients without graft versus host disease)(p=0.018) suggesting no overt absence of immune regulation in the late onset form of the disease. Conclusions Imbalance of effector and regulatory CD4 T cells is a signature of graft versus host disease in this transplantation protocol.

Dendritic cell derived exosomes are able to mediate and modulate immune responses in vivo by semi-direct T cell activation. T cells can eradicate primary, metastatic, relapsed tumours and ameliorate otherwise fatal viral infections. Not surprisingly activation and expansion of T cells has become one of the main focuses for immunotherapy. Using nanotechnology, we have developed targeted and traceable in vivo artificial exosomes by coating liposomes (FDA approved) with an optimized number of MHC Class I/peptide complexes and a selected specific range of ligands for adhesion, early activation, late activation and survival T cell receptors. These targeted artificial exosomes are traceable both in vitro and in vivo via fluorescent and Magnetic Resonance Imaging and facilitate imaging of specific areas by applying localised nuclear magnetic interactions of hydrogens via super paramagnetic labels. Here we show that artificial exosomes activate and expand functional antigen specific T cells at sufficient levels. This novel system has potential basic and clinical applications in immunology where the study of membrane interactions is desired.