Normalizing transformations for dead-time-modified Poisson counting distributions

Approximate normalizing transformations are derived for Poisson counting systems affected by nonparalyzable and paralyzable dead time. In the nonparalyzable case the transformation takes the form of a simple inverse hyperbolic function whereas in the paralyzable case it is an inverse trigonometric function. The results are expected to find use in neural counting, photon counting, and nuclear counting, as well as in queuing theory.     

Synthesis of gamma-L-glutaminyl-[3,5-3H]4-hydroxybenzene and the study of reactions catalyzed by the tyrosinase of Agaricus bisporus.

gamma-L-Glutaminyl-[3,5-3H]4-hydroxybenzene was synthesized in order to study the kinetics of its hydroxylation by tyrosinase purified from Agaricus bisporus and to explore its role in the induction of the dormant state in the spores of this species. It was found to be unique among the monophenolic substrates for tyrosinase in that the lag period for the hydroxylation reaction decreased with increasing substrate concentration. Unlike previously studied compounds, this phenol appeared to function as an electron donor, allowing it to act as its own co-substrate in the hydroxylation reaction. Its catechol product, gamma-L-glutaminyl-3,4-dihydroxybenzene, was found to be a superior co-substrate, yielding its electrons more readily (oxidation peak potential +0.18 V as compared with +0.65 V for the phenol). In situ periodate oxidation of gamma-L-glutaminyl-3,4-dihydroxybenzene to gamma-L-glutaminyl-3,4-benzoquinone confirmed the co-substrate role of the catechol in the hydroxylation reaction. The tyrosinase-mediated oxidation of gamma-L-glutaminyl-3,4-dihydroxybenzene to gamma-L-glutaminyl-3,4-benzoquinone occurred with an apparent Km = 1.54 mM and Vmax = 0.36 mmol/min/mg of enzyme. gamma-L-Glutaminyl-4-hydroxybenzene acted as an inhibitor of the oxidation reaction.     

Expression, localization, and functional activity of TL1A, a novel Th1-polarizing cytokine in inflammatory bowel disease

TL1A is a novel TNF-like factor that acts as a costimulator of IFN-gamma secretion through binding to the death domain-containing receptor, DR3. The aim of this study was to test the hypothesis that TL1A may play an important role in inflammatory bowel disease (IBD) by functioning as a Th1-polarizing cytokine. The expression, cellular localization, and functional activity of TL1A and DR3 were studied in intestinal tissue specimens as well as isolated lamina propria mononuclear cells from IBD patients and controls. TL1A mRNA and protein expression was up-regulated in IBD, particularly in involved areas of Crohn's disease (CD; p < 0.03 vs control). TL1A production was localized to the intestinal lamina propria in macrophages and CD4(+) and CD8(+) lymphocytes from CD patients as well as in plasma cells from ulcerative colitis patients. The amount of TL1A protein and the number of TL1A-positive cells correlated with the severity of inflammation, most significantly in CD. Increased numbers of immunoreactive DR3-positive T lymphocytes were detected in the intestinal lamina propria from IBD patients. Addition of recombinant human TL1A to cultures of PHA-stimulated lamina propria mononuclear from CD patients significantly augmented IFN-gamma production by 4-fold, whereas a minimal effect was observed in control patients. Our study provides evidence for the first time that the novel cytokine TL1A may play an important role in a Th1-mediated disease such as CD.     

A mammalian sequence-dependent upstream open reading frame mediates polyamine-regulated translation in yeast

In mammals, control of S-adenosylmethionine decarboxylase (AdoMetDC) translation is one component of a feedback network that regulates intracellular levels of the polyamines, spermidine, and spermine. AdoMetDC mRNA from mammals contains a highly conserved upstream open reading frame (uORF) within its leader sequence that confers polyamine-regulated suppression of translation on the associated downstream cistron. This regulation is mediated through an interaction that depends on the amino acid sequence of the uORF-encoded hexapeptide. It remains to be shown whether polyamines participate directly in this interaction or indirectly through a specialized signal transduction pathway. We show that Saccharomyces cerevisiae does not have a uORF associated with its AdoMetDC gene (SPE2) and that ribosome loading on the SPE2 mRNA is not positively influenced by polyamine depletion, as it is in mammalian cells. Nevertheless, the mammalian AdoMetDC uORF, when introduced into a polyamine auxotroph of yeast, conferred polyamine regulation of both translational efficiency and ribosome loading on the associated mRNA. This regulatory activity depended on the amino acid sequence encoded by the fourth and fifth codons of the uORF, as in mammalian cells. The fact that the regulatory properties of this mammalian translational control element are quite similar in both mammalian and yeast cells suggests that a specialized signal transduction pathway is not required. Rather, it seems likely that polyamines may be directly participating in an interaction between the uORF-encoded peptide and a constitutive component of the translation machinery, which leads to inhibition of ribosome activity.