Electronically ascertained extended pedigrees in breast cancer genetic counseling.

A comprehensive pedigree, usually provided by the counselee and verified by medical records, is essential for risk assessment in cancer genetic counseling. Collecting the relevant information is time-consuming and sometimes impossible. We studied the use of electronically ascertained pedigrees (EGP). The study group comprised women (n = 1352) receiving HBOC genetic counseling between December 2006 and December 2016 at Landspitali in Iceland. EGP's were ascertained using information from the population-based Genealogy Database and Icelandic Cancer Registry. The likelihood of being positive for the Icelandic founder BRCA2 pathogenic variant NM_000059.3:c.767_771delCAAAT was calculated using the risk assessment program Boadicea. We used this unique data to estimate the optimal size of pedigrees, e.g., those that best balance the accuracy of risk assessment using Boadicea and cost of ascertainment. Sub-groups of randomly selected 104 positive and 105 negative women for the founder BRCA2 PV were formed and Receiver Operating Characteristics curves compared for efficiency of PV prediction with a Boadicea score. The optimal pedigree size included 3° relatives or up to five generations with an average no. of 53.8 individuals (range 9-220) (AUC 0.801). Adding 4° relatives did not improve the outcome. Pedigrees including 3° relatives are difficult and sometimes impossible to generate with conventional methods. Pedigrees ascertained with data from pre-existing genealogy databases and cancer registries can save effort and contain more information than traditional pedigrees. Genetic services should consider generating EGP's which requires access to an accurate genealogy database and cancer registry. Local data protection laws and regulations have to be addressed.

"Supercharged Cells" for delivery of recombinant human iduronate-2-sulfatase.

Expression of iduronate-2-sulfatase (IDS) from three different promoters in four retroviral vectors was studied in peripheral blood lymphocytes from patients with Hunter syndrome (PBL(MPS)), i.e., the LTR in vectors L2SN and L2, avian beta-actin promoter in LB2, and the CMV early promoter in LNC2. PBL(MPS) were exposed to packaging cell supernatant resulting in transduction frequencies ranging 10-fold from 5 to 49%. Surprisingly, IDS activities were equally high in all transduced lymphocyte populations: 515 U/mg/h in PBL(MPS)-L2SN, 734 in PBL(MPS)-LB2, 352 in PBL(MPS)-L2, and 389 in PBL(MPS)-LNC2 compared to controls (<10 in PBL(MPS)-LXSN or PBL(MPS)). The half-life of endocytosed IDS in PBL(MPS) was 1.9 days. However, the level of lymphocyte IDS activity from proviral expression was found to be only a fraction of the total, a large portion being derived from reuptake of enzyme from murine packaging cells, i.e., a "second source" of enzyme. Therefore, measurement of transgene lysosomal enzyme soon after exposure of target cells to vector supernatant may yield a gross overestimate of long-term transgene expression by transduced cells. Nevertheless, patient fibroblasts cocultured with transduced PBL(MPS) had reduced (35)SO(4)-GAG accumulation, levels similar to those of normal fibroblasts. These studies revealed a broadly applicable phenomenon: cells can be charged with a lysosomal enzyme to levels much higher than those found in nature. By "supercharging" cells with a lysosomal protein (or other molecule bearing the mannose-6-phosphate ligand), such cells may be exploited as vehicles for systemic delivery of therapeutic or diagnostic agents.

Preclinical studies of lymphocyte gene therapy for mild Hunter syndrome (mucopolysaccharidosis type II).

To explore the feasibility of ex vivo lymphocyte gene therapy for mild Hunter syndrome (mucopolysaccharidosis type II), we evaluated retrovirus-mediated gene transfer of the iduronate-2-sulfatase (IDS) coding sequence into peripheral blood lymphocytes from enzyme-deficient individuals (PBLMPS). Moloney murine leukemia virus-derived retroviral vectors were constructed by inserting the IDS cDNA under transcriptional regulation of the long terminal repeat (LTR) (in vector L2SN) or the cytomegalovirus (CMV) early promoter (vector LNC2). High-titer virus-producer cells were generated using amphotropic PA317 packaging cells. After 3 days of in vitro stimulation of T lymphocytes with anti-CD3 antibody and interleukin-2 (IL-2), PBLMPS were transduced once on each of the next 3 days. Seven to 21 days later, cultured PBLMPS were evaluated for gene transfer and IDS specific activity. Heterogeneous populations of L2SN-transduced PBLMPS had high levels of IDS enzyme activity (456 U/mg per hr +/- SD 292) despite a gene transfer efficiency of 5% or less. Owing to overexpression of IDS in that percentage of PBLMPS successfully transduced, IDS activity was increased above the deficiency found in patients with Hunter syndrome (< 20 U/mg per hr) to a level comparable with that of normal individuals (mean activity of uncultured normal leukocytes 807 U/mg per hr; SD 252). Reduced 35SO4-glucosaminoglycan (GAG) accumulation was observed in PBLMPS that had been transduced with L2SN, or when PBLMPS were grown in medium that had been "conditioned" by growth of L2SN-transduced cells. This latter result indicated that metabolic cross-correction occurred by means of intercellular enzyme transfer. These studies of retrovirus-mediated expression and metabolic correction, finding near-normal levels of IDS in cultured PBLMPS and metabolic correction, demonstrate the potential for treatment of mild, nonneuropathic Hunter syndrome by means of ex vivo lymphocyte gene therapy.

Retrovirus-mediated transduction of an engineered intron-containing purine nucleoside phosphorylase gene.

We constructed and tested several retroviral vectors containing abbreviated purine nucleoside phosphorylase (PNP) genes in the reverse orientation, a strategy compatible with transduction of intron-containing genes. We observed two types of deletions in these vectors after one round of replication: (i) Deletions flanked by direct repeats with one copy of the repeat retained in the provirus, presumably resulting from reverse transcriptase slippage during (-) strand DNA synthesis. (ii) Deletions due to fortuitous splice sites in the PNP complementary strand. Two splice donor sites and three splice acceptor sites were identified in a 3.0-kb PNP minigene. We found that the splice donor sites (but not the splice acceptor sites) could be predicted by sequence analysis of the PNP complementary strand. To increase the frequency of intact PNP gene transduction, we introduced sequence modifications: The putative PNP polyadenylation signal and a truncated 117-bp 3' flank were recovered from a rearranged provirus and inserted in place of a 1.2-kb genomic 3' flank. Sequences associated with deletions were eliminated from the PNP 5' untranslated region, and two fortuitous splice donor signals in the complementary strand were inactivated. A retroviral vector LN-PMG11, containing the engineered 2.9-kb PNP minigene in the reverse orientation, was transduced intact in 23% (5/22) of clones after one round of replication and in 87% (20/23) of clones after a second round of replication from two primary virus producer clones. Directed mutagenesis of sequences preventing intact retroviral transduction thus provided a 2.9-kb PNP gene that was transduced intact and expressed at a high level.

Prevalence of iron deficiency and iron overload in the adult Icelandic population.

The aim of this cross-sectional study was to estimate the prevalence of iron deficiency and overload in the adult population in Iceland, a developed Scandinavian country. The study population consisted of 4240 individuals aged 25-74 years randomly selected from the national roster. Basic hematological, S-iron, S-total iron binding capacity (TIBC), and S-ferritin measurements were obtained on 2588 individuals (61.0%). The results indicated unusually large iron stores in the adult Icelandic population and significantly larger iron stores in the rural compared to the urban population. Iron deficiency was rare except in urban premenopausal women, where 1 in 4 showed evidence of iron deficiency and 3.2% had iron deficiency anemia. Seven patients with hereditary hemochromatosis were identified from a subgroup of 1887 subjects, resulting in a prevalence of 0.37%. Two of the hereditary hemochromatosis patients had been gastrectomized. Measures to improve the iron balance in urban premenopausal women cannot therefore include increased iron fortification of food but must be more directed towards the target group.