Microdeletion of exon 3 in the HBA2 gene associated with mild α-thalassemia trait.

A mother and son presented with mild symptoms of thalassemia trait. Polymerase chain reaction (PCR) amplification of their globin genes revealed a previously unreported 203 bp microdeletion in the HBA2 gene (NG_000006.1:g.34305_34507del; HBA2:c301-30_*44del). Both mother and son were heterozygous for the deletion which included DNA coding for all of exon 3. DNA sequence analysis revealed a six nucleotide repeat (5'-CGGGCC-3') flanking the breakpoint, suggesting that the microdeletion may have arisen as a result of reciprocal recombination within the HBA2 alleles.

Optimization of fermentation parameters in phage production using response surface methodology.

Previously, we used computer-controlled fermentation technology to improve the yield of filamentous phage produced in Escherichia coli by 10-fold (Grieco et al., Bioprocess Biosyst Eng 32:773-779, 2009). In the current study, three major fermentation parameters (temperature, dissolved oxygen [DO], and pH) were investigated using design of experiments (DOE) methodology. Response surface methodology (RSM) was employed to create a process model and determine the optimal conditions for maximal phage production. The experimental data fitted best to a quadratic model (p < 0.0001). Temperature and pH, but not DO, proved to be significant variables. The model predicted a theoretical optimal condition for maximal bacteriophage production at temperature of 28.1 °C and pH 6.9. A validation run resulted in phage production [3.49 × 10(11) transducing units (TU)/mL] comparable to the predicted value (2.86 × 10(11) TU/mL). This represented a 7-fold increase in phage production above that obtained without optimization, resulting in a 70-fold increase above that achieved by shake flask culture alone.

Human hephaestin expression is not limited to enterocytes of the gastrointestinal tract but is also found in the antrum, the enteric nervous system, and pancreatic {beta}-cells.

Hephaestin (Hp) is a membrane protein with ferroxidase activity that converts Fe(II) to Fe(III) during the absorption of nutritional iron in the gut. Using anti-peptide antibodies to predicted immunogenic regions of rodent Hp, previous immunocytochemical studies in rat, mouse, and human gut tissues localized Hp to the basolateral membranes of the duodenal enterocytes where the Hp was predicted to aid in the transfer of Fe(III) to transferrin in the blood. We used a recombinant soluble form of human Hp to obtain a high-titer polyclonal antibody to Hp. This antibody was used to identify the intracellular location of Hp in human gut tissue. Our immunocytochemical studies confirmed the previous localization of Hp in human enterocytes. However, we also localized Hp to the entire length of the gastrointestinal tract, the antral portion of the stomach, and to the enteric nervous system (both the myenteric and submucous plexi). Hp was also localized to human pancreatic beta-cells. In addition to its expression in the same cells as Hp, ferroportin was also localized to the ductal cells of the exocrine pancreas. The localization of the ferroxidase Hp to the neuronal plexi and the pancreatic beta cells suggests a role for the enzymatic function of Hp in the protection of these specialized cell types from oxidative damage.

Two new examples of Hb St. Etienne [beta 92(F8)HisGln] in association with venous thrombosis.

Hb St. Etienne [beta92(F8)HisGln] (also known as Hb Istanbul) is a rare unstable beta-globin chain variant that has been described in only three reports involving four patients. We report two individuals in a family of Scottish extraction whose members had been erroneously diagnosed to have hereditary spherocytosis (HS) and have now been shown to be heterozygotes for Hb St. Etienne. They also had venous thrombotic events with minimal provocation. This family illustrates the difficulties in identifying the cause of chronic hemolytic anemia and highlights the possible contribution of chronic hemolysis to increased risk of thrombosis.

Blood iron homeostasis: newly discovered proteins and iron imbalance.

In biological systems, iron exerts 2 contrasting effects. The chemical reactivity of iron is essential for the biological activities of proteins such as hemoglobin, ribonucleotide reductase, the cytochromes, and aconitases. However, free iron in a cell has the propensity to generate free radicals which can damage cellular components containing proteins, lipids, and nucleic acids. To maintain the balance between iron as an essential nutrient and iron as a potential cytotoxin, a number of biological protective mechanisms have evolved. As shown in the thalassemias, iron imbalance can have devastating effects on human health. Recently, several new proteins have been described that play critical roles in iron regulation including the master regulator of iron metabolism (hepcidin). In this review, we discuss the new knowledge that has arisen from studies in yeast and in humans, and we show how these studies are shedding new light on some well-known human disorders.