St. Jude Children's Research Hospital

About: St. Jude Children's Research Hospital is a healthcare organization based out in Memphis, Tennessee, United States. It is known for research contribution in the topics: Population & Virus. The organization has 9344 authors who have published 19233 publications receiving 1233399 citations. The organization is also known as: St. Jude Children's Hospital & St. Jude Hospital.

Establishment of a pediatric oncology program and outcomes of childhood acute lymphoblastic leukemia in a resource-poor area.

Abstract: Results The 5-year event-free survival improved steadily: 32% (95% CI, 21%43%) in the early period, 47% (95% CI, 36%-58%) in the middle period, and 63% (95% CI, 55%-71%) in the recent period. The probability of cause-specific treatment failure in the early, middle, and late periods, respectively, within 1 year of diagnosis was 14% vs 3.8% vs 3.3% for relapse; 6.0% vs 12% vs 9.8% for death from infection; 2.4% vs 13% vs 4.2% for death from noninfectious toxicity; and 16% vs 1.3% vs 0.5% for abandonment of therapy. Conclusion Treatment of childhood ALL in a dedicated pediatric oncology unit using a comprehensive multidisciplinary team approach, protocol-based therapy, and local support and funding is associated with improved outcomes in a resource-poor area.

Racial and gender differences in N-acetyltransferase, xanthine oxidase, and CYP1A2 activities.

Abstract: Background The urinary molar concentration ratios of several caffeine metabolites are indicators of specific drug metabolizing enzyme activities. The ratios of 5-acetyl-amino-6-formylamino-3-methyluracil (AFMU) to 1-methylxanthine (1X), AFMU to 1X plus 1-methyluric acid (1U), and AFMU to 1X + 1U + AFMU are indicative of N-acetyltransferase (NAT) activity; the ratios of 1U to 1X and 1U to 1U + 1X indicate xanthine oxidase activity; and the ratio of the sum of 7-demethylated metabolites (AFMU + 1X + 1U) to the precursor for all three compounds, paraxanthine (PX), is a putative indicator of CYP1A2 oxidative activity. Our objective was to discern whether there are race-, gender-, and age-related differences in these indexes of drug-metabolizing activity. Methods In 342 normal healthy unrelated subjects, metabolites were measured in urine collected after administration of low-dose caffeine. Results By two-way analysis of variance, NAT activity was higher in black subjects than in white subjects when assessed as AFMU/(1U + 1X) or as AFMU/(AFMU + 1U + 1X) (p = 0.001 and p = 0.002, respectively), but less so by use of AFMU/1X (p = 0.08). Xanthine oxidase activity, as assessed by 1U/1X or as 1U/(1U + IX), was lower in black subjects than in white subjects (p = 0.02 and/> = 0.001, respectively) and was lower in males than in females (p = 0.001 for both ratios). Females had higher AFMU/1X ratios (p = 0.03) because of higher xanthine oxidase activity. In a model in which AFMU/1X was the dependent variable and race, sex, age, and an index of xanthine oxidase (1U/1X) were independent variables, only race and 1U/1X were significant determinants of this NAT index (p = 0.003 and p < 0.001, respectively). The CYP1A2 ratio was lower in black subjects (p = 0.036) and in females (p = 0.015). Conclusion Racial and gender differences in xanthine oxidase activity render the AFMU/1X ratio less reliable as an assessment of NAT activity in a heterogeneous population compared with the AFMU/(1U + 1X) or AFMU/(AFMU + 1U + 1X) ratios. The observed racial and gender differences in NAT, xanthine oxidase, and CYP1A2 activities may have implications for racial and gender differences in drug effects and carcinogen biotransformation. Clinical Pharmacology and Therapeutics (1992) 52, 643–658; doi:10.1038/clpt.1992.203

Treg cells require the phosphatase PTEN to restrain TH1 and TFH cell responses.

Abstract: The interplay between effector T cells and regulatory T cells (Treg cells) is crucial for adaptive immunity, but how Treg cells control diverse effector responses is elusive. We found that the phosphatase PTEN links Treg cell stability to repression of type 1 helper T cell (TH1 cell) and follicular helper T cell (TFH cell) responses. Depletion of PTEN in Treg cells resulted in excessive TFH cell and germinal center responses and spontaneous inflammatory disease. These defects were considerably blocked by deletion of interferon-γ, indicating coordinated control of TH1 and TFH responses. Mechanistically, PTEN maintained Treg cell stability and metabolic balance between glycolysis and mitochondrial fitness. Moreover, PTEN deficiency upregulates activity of the metabolic checkpoint kinase complex mTORC2 and the serine-threonine kinase Akt, and loss of this activity restores functioning of PTEN-deficient Treg cells. Our studies establish a PTEN-mTORC2 axis that maintains Treg cell stability and coordinates Treg cell-mediated control of effector responses.

Continuing challenges in influenza

Abstract: Influenza is an acute respiratory disease in mammals and domestic poultry that emerges from zoonotic reservoirs in aquatic birds and bats. Although influenza viruses are among the most intensively studied pathogens, existing control options require further improvement. Influenza vaccines must be regularly updated because of continuous antigenic drift and sporadic antigenic shifts in the viral surface glycoproteins. Currently, influenza therapeutics are limited to neuraminidase inhibitors; novel drugs and vaccine approaches are therefore urgently needed. Advances in vaccinology and structural analysis have revealed common antigenic epitopes on hemagglutinins across all influenza viruses and suggest that a universal influenza vaccine is possible. In addition, various immunomodulatory agents and signaling pathway inhibitors are undergoing preclinical development. Continuing challenges in influenza include the emergence of pandemic H1N1 influenza in 2009, human infections with avian H7N9 influenza in 2013, and sporadic human cases of highly pathogenic avian H5N1 influenza. Here, we review the challenges facing influenza scientists and veterinary and human public health officials; we also discuss the exciting possibility of achieving the ultimate goal of controlling influenza's ability to change its antigenicity.