GWAS of Dizygotic Twinning in an Enlarged Australian Sample of Mothers of DZ Twins.

Female fertility is a complex trait with age-specific changes in spontaneous dizygotic (DZ) twinning and fertility. To elucidate factors regulating female fertility and infertility, we conducted a genome-wide association study (GWAS) on mothers of spontaneous DZ twins (MoDZT) versus controls (3273 cases, 24,009 controls). This is a follow-up study to the Australia/New Zealand (ANZ) component of that previously reported (Mbarek et al., 2016), with a sample size almost twice that of the entire discovery sample meta-analysed in the previous article (and five times the ANZ contribution to that), resulting from newly available additional genotyping and representing a significant increase in power. We compare analyses with and without male controls and show unequivocally that it is better to include male controls who have been screened for recent family history, than to use only female controls. Results from the SNP based GWAS identified four genomewide significant signals, including one novel region, ZFPM1 (Zinc Finger Protein, FOG Family Member 1), on chromosome 16. Previous signals near FSHB (Follicle Stimulating Hormone beta subunit) and SMAD3 (SMAD Family Member 3) were also replicated (Mbarek et al., 2016). We also ran the GWAS with a dominance model that identified a further locus ADRB2 on chr 5. These results have been contributed to the International Twinning Genetics Consortium for inclusion in the next GWAS meta-analysis (Mbarek et al., in press).

Effect of cord blood processing on transplantation outcomes after single myeloablative umbilical cord blood transplantation.

Variations in cord blood manufacturing and administration are common, and the optimal practice is not known. We compared processing and banking practices at 16 public cord blood banks (CBB) in the United States and assessed transplantation outcomes on 530 single umbilical cord blood (UCB) myeloablative transplantations for hematologic malignancies facilitated by these banks. UCB banking practices were separated into 3 mutually exclusive groups based on whether processing was automated or manual, units were plasma and red blood cell reduced, or buffy coat production method or plasma reduced. Compared with the automated processing system for units, the day 28 neutrophil recovery was significantly lower after transplantation of units that were manually processed and plasma reduced (red cell replete) (odds ratio, .19; P = .001) or plasma and red cell reduced (odds ratio, .54; P = .05). Day 100 survival did not differ by CBB. However, day 100 survival was better with units that were thawed with the dextran-albumin wash method compared with the "no wash" or "dilution only" techniques (odds ratio, 1.82; P = .04). In conclusion, CBB processing has no significant effect on early (day 100) survival despite differences in kinetics of neutrophil recovery.

Optimising cryopreservation protocols for haematopoietic progenitor cells: a methodological approach for umbilical cord blood.

Current cryopreservation protocols for haematopoietic cells have developed largely empirically and there is no consensus on an optimal method of preservation. These protocols, though providing sufficient cells to permit engraftment, can lead to cell loss of the order of 50 percent. In the context of umbilical cord blood such losses are unacceptable. Whilst an empirical approach can provide an acceptable level of recovery, the cryopreservation process can only be optimised by adopting a methodological approach. This paper provides an overview of just such an approach as illustrated by a study on CD34 cells from umbilical cord blood. It involves firstly the determination of membrane permeability parameters that can then be used to model safe addition and elution protocols for the chosen cryoprotectant, in this case dimethyl sulphoxide. This in turn permits cryoprotectant toxicity to be evaluated free from the confounding effect of osmotic damage caused by inappropriate addition and elution protocols. Finally, non-toxic concentrations of cryoprotectant may be investigated in a cooling rate study to provide an optimal cryopreservation protocol. Using the model, the effect on CD34 cells of current addition and elution protocols was also examined.

Cryopreservation of umbilical cord blood: 1. Osmotically inactive volume, hydraulic conductivity and permeability of CD34(+) cells to dimethyl sulphoxide.

Umbilical cord blood (UCB) is an accepted treatment for the reconstitution of bone marrow function following myeloablative treatment predominantly in children and juveniles. Current cryopreservation protocols use methods established for bone marrow and peripheral blood progenitors cells that have largely been developed empirically. Such protocols can result in losses of up to 50% of the nucleated cell population: losses unacceptable for cord blood. The design of optimal cryopreservation regimes requires the development of addition and elution protocols for the chosen cryoprotectant; protocols that minimise damaging osmotic transients. The biophysical parameters necessary to model the addition and elution of dimethyl sulphoxide to and from cord blood CD34(+) cells have been established. An electronic particle counting method was used to establish the volumetric response of CD34(+) cells to changes in osmolality of the suspending medium. The non-osmotic volume of the cell was 0.27 of the cells isotonic volume. The permeation kinetics of CD34(+) cells to water and dimethyl sulphoxide were investigated at two temperatures, +1.5 and +20 degrees C. Values for the hydraulic conductivity were 3.2 x 10(-8) and 2.8 x 10(-7)cm/atm/s, respectively. Values for the permeability of dimethyl sulphoxide at these temperatures were 4.2 x 10(-7) and 7.4 x 10(-6)cm/s, respectively. Clonogenic assays indicated that the ability of CD34(+) cells to grow and differentiate was significantly impaired outside the limits 0.6-4x isotonic. Based on the Boyle van't Hoff plot, the tolerable limits for cell volume excursion were therefore 45-140% of isotonic volume. The addition and elution of cryoprotectant was modelled using a two-parameter model. Current protocols for the addition of cryoprotectant based on exposure at +4 degrees C would require additional time for complete equilibration of the cryoprotectant. During the elution phase current protocols are likely to cause CD34(+) cells to exceed tolerable limits. The addition of a short holding period during elution reduces the likelihood of this occurring.

Cryopreservation of umbilical cord blood: 2. Tolerance of CD34(+) cells to multimolar dimethyl sulphoxide and the effect of cooling rate on recovery after freezing and thawing.

Cryopreservation protocols for umbilical cord blood have been based on methods established for bone marrow (BM) and peripheral blood stem cells (PBSC). The a priori assumption that these methods are optimal for progenitor cells from UCB has not been investigated systematically. Optimal cryopreservation protocols utilising penetrating cryoprotectants require that a number of major factors are controlled: osmotic damage during the addition and removal of the cryoprotectant; chemical toxicity of the cryoprotectant to the target cell and the interrelationship between cryoprotectant concentration and cooling rate. We have established addition and elution protocols that prevent osmotic damage and have used these to investigate the effect of multimolar concentrations of Me(2)SO on membrane integrity and functional recovery. We have investigated the effect of freezing and thawing over a range of cooling rates and cryoprotectant concentrations. CD34(+) cells tolerate up to 60 min exposure to 25% w/w (3.2M) Me(2)SO at +2 degrees C with no significant loss in clonogenic capacity. Exposure at +20 degrees C for a similar period of time induced significant damage. CD34(+) cells showed an optimal cooling range between 1 degrees C and 2.5 degrees C/min. At or above 1 degrees C/min, increasing the Me(2)SO concentration above 10% w/w provided little extra protection. At the lowest cooling rate tested (0.1 degrees C/min), increasing the Me(2)SO concentration had a statistically significant beneficial effect on functional recovery of progenitor cells. Our findings support the conclusion that optimal recovery of CD34(+) cells requires serial addition of Me(2)SO, slow cooling at rates between 1 degrees C and 2.5 degrees C/min and serial elution of the cryoprotectant after thawing. A concentration of 10% w/w Me(2)SO is optimal. At this concentration, equilibration temperature is unlikely to be of practical importance with regard to chemical toxicity.