Mutations in the alanine-glyoxylate amino transferase gene (AGXT) are responsible for primary hyperoxaluria type I, a rare disease characterized by excessive hepatic oxalate production that leads to renal failure. We generated a null mutant mouse by targeted mutagenesis of the homologous gene, Agxt, in embryonic stem cells. Mutant mice developed normally, and they exhibited hyperoxaluria and crystalluria. Approximately half of the male mice in mixed genetic background developed calcium oxalate urinary stones. Severe nephrocalcinosis and renal failure developed after enhancement of oxalate production by ethylene glycol administration. Hepatic expression of human AGT1, the protein encoded by AGXT, by adenoviral vector-mediated gene transfer in Agxt ؊/؊ mice normalized urinary oxalate excretion and prevented oxalate crystalluria. Subcellular fractionation and immunofluorescence studies revealed that, as in the human liver, the expressed wild-type human AGT1 was predominantly localized in mouse hepatocellular peroxisomes, whereas the most common mutant form of AGT1 (G170R) was localized predominantly in the mitochondria.gene therapy ͉ knockout mouse ͉ oxalate ͉ urolithiasis ͉ nephrocalcinosis
The
use of NMR chiral solvating agents (CSAs) for the analysis
of enantiopurity has been known for decades, but has been supplanted
in recent years by chromatographic enantioseparation technology. While
chromatographic methods for the analysis of enantiopurity are now
commonplace and easy to implement, there are still individual compounds
and entire classes of analytes where enantioseparation can prove extremely
difficult, notably, compounds that are chiral by virtue of very subtle
differences such as isotopic substitution or small differences in
alkyl chain length. NMR analysis using CSAs can often be useful for
such problems, but the traditional approach to selection of an appropriate
CSA and the development of an NMR-based analysis method often involves
a trial-and-error approach that can be relatively slow and tedious.
In this study we describe a high-throughput experimentation approach
to the selection of NMR CSAs that employs automation-enabled screening
of prepared libraries of CSAs in a systematic fashion. This approach
affords excellent results for a standard set of enantioenriched compounds,
providing a valuable comparative data set for the effectiveness of
CSAs for different classes of compounds. In addition, the technique
has been successfully applied to challenging pharmaceutical development
problems that are not amenable to chromatographic solutions. Overall,
this methodology provides a rapid and powerful approach for investigating
enantiopurity that compliments and augments conventional chromatographic
approaches.
BackgroundThe characterization of DNA replication origins in yeast has shed much light on the mechanisms of initiation of DNA replication. However, very little is known about the evolution of origins or the evolution of mechanisms through which origins are recognized by the initiation machinery. This lack of understanding is largely due to the vast evolutionary distances between model organisms in which origins have been examined.ResultsIn this study we have isolated and characterized autonomously replicating sequences (ARSs) in Lachancea kluyveri - a pre-whole genome duplication (WGD) budding yeast. Through a combination of experimental work and rigorous computational analysis, we show that L. kluyveri ARSs require a sequence that is similar but much longer than the ARS Consensus Sequence well defined in Saccharomyces cerevisiae. Moreover, compared with S. cerevisiae and K. lactis, the replication licensing machinery in L. kluyveri seems more tolerant to variations in the ARS sequence composition. It is able to initiate replication from almost all S. cerevisiae ARSs tested and most Kluyveromyces lactis ARSs. In contrast, only about half of the L. kluyveri ARSs function in S. cerevisiae and less than 10% function in K. lactis.ConclusionsOur findings demonstrate a replication initiation system with novel features and underscore the functional diversity within the budding yeasts. Furthermore, we have developed new approaches for analyzing biologically functional DNA sequences with ill-defined motifs.
Emerging evidence demonstrates that miRNAs, a new family of key mRNA regulatory molecules, have crucial roles in controlling and modulating immunity. Their contribution to myasthenia gravis (MG), a T cell-dependent, antibody-mediated nervous system autoimmune disease, has not been thoroughly investigated. In the present study, using a highly sensitive microarray-based approach, we identified 11 miRNAs with differential expression between Peripheral Blood Mononuclear Cells (PBMC) from experimental autoimmune MG (EAMG) rats and control rats. miR-145 is one of the most significantly down-regulated miRNAs in PBMC from EAMG rats. Down-regulation of miR-145 expression was confirmed in PBMC and CD4+CD25- T cells (T effector cells) from both EAMG rats and MG patients by real-time PCR. Bioinformatics target prediction identified two crucial immune-related molecules-CD28 and NFATc1, as putative targets of miR-145. Furthermore, miR-145 inhibited CD28 and NFATc1 expression by directly targeting their 3'-UTRs, which was abolished by mutation of the miR-145 and CD28/NFATc1 binding sites. In vitro up-regulation of miR-145 in CD4+ T cells can significantly reduce CD28 protein levels accompanied by decreased proliferative response. In a dendritic cell (DC)-T cell coculture system, overexpression of miR-145 in AChR-specific CD4+ T cells suppresses NFATc1 expression and T Helper 17 cells level. Finally, we observed that administration of lentiviral-miR-145 decreased the severity of ongoing, established EAMG with decreased IL-17 production, and also decreased serum anti-AChR IgG levels. Our studies provide an important new insight into the pathogenesis of EAMG and MG, which may open a new perspective for the development of effective gene therapy for EAMG/MG.
L37 ConclusionsA highly successful procedure has been developed which allows deposition of thin-film ceramics on highly porous substrates. The methodology is inexpensive and scalable. Thin-film SOFCs fabricated using these techniques demonstrate performances of close to 2 W/cm2 at 800°C. Current interrupt techniques indicate the majority of the voltage loss at high current density is due to ohmic losses, most likely associated with cathode/electrolyte contact resistance (0.1 i cm2). The exceptional performance of the thinfilm SOFC5 implies that reduced temperature operation is possible while still maintaining high power density.
ABSTRACTHighly selective chemical etching of Si vs. epitaxial Si1 Ge in NH4OH solution has been investigated. It was found the selectivity was better than 80:1 even for a Si09Ge0, in 10 weight percent(w/o) NH4OH at 75°C. As the fraction xof Ge was increased, higher selectivity was obtained due to the decrease of the etch rate of the Si -The achievement of the excellent selectivity in a Si/Si Ge/Si heterostructure was clearly demonstrated by scanning electron microscopy. Surfaces of etched Si1, ,Ge, samples were analyzed using x-ray photoelectron spectroscopy. The high etch selectivity obtained in NH4OH is essentially due to a passivation-film effect at the Si1Ge surface.
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