Method development for fecal lipidomics profiling.

Robust methodologies for the analysis of fecal material will facilitate the understanding of gut (patho)physiology and its role in health and disease and will help improve care for individual patients, especially high-risk populations, such as premature infants. Because lipidomics offers a biologically and analytically attractive approach, we developed a simple, sensitive, and quantitatively precise method for profiling intact lipids in fecal material. The method utilizes two separate, complementary extraction chemistries, dichloromethane (DCM) and a methyl tert-butyl ether/hexafluoroisopropanol (MTBE) mixture, alone or with high pressure cycling.

Pressure cycling technology (PCT) reduces effects of inhibitors of the PCR.

A common problem in the analysis of forensic human DNA evidence, or for that matter any nucleic acid analysis, is the presence of contaminants or inhibitors. Contaminants may copurify with the DNA, inhibiting downstream PCR or they may present samples effectively as containing fewer templates than exist in the PCR, even when the actual amount of DNA is adequate. Typically, these challenged samples exhibit allele imbalance, allele dropout, and sequence-specific inhibition, leading to interpretational difficulties.

Isolation of functional mitochondria from rat kidney and skeletal muscle without manual homogenization.

Isolation of functional and intact mitochondria from solid tissue is crucial for studies that focus on the elucidation of normal mitochondrial physiology and/or mitochondrial dysfunction in conditions such as aging, diabetes, and cancer. There is growing recognition of the importance of mitochondria both as targets for drug development and as off-target mediators of drug side effects. Unfortunately, mitochondrial isolation from tissue is generally carried out using homogenizer-based methods that require extensive operator experience to obtain reproducible high-quality preparations.

Mouse embryonic stem cells and preimplantation embryos require signaling through the phosphatidylinositol 3-kinase pathway to suppress apoptosis.

Whereas most mammalian cells require extracellular signals to suppress apoptosis, preimplantation embryos can survive and develop to the blastocyst stage in defined medium without added serum or growth factors. Since cells of these embryos are capable of undergoing apoptosis, it has been suggested that their lack of dependence upon exogenous growth factors results from the production of endogenous growth factors that suppress apoptosis by an autocrine signaling mechanism. In the present study, we have examined the growth factor requirements and intracellular signaling pathways that suppress apoptosis in both mouse preimplantation embryos and embryonic stem (ES) cells, which are derived from the blastocyst inner cell mass.

Functional analysis of sperm from c-mos(-/-) mice.

The c-mos protooncogene, which is expressed predominantly in male and female germ cells, is crucial for normal oocyte meiosis and female fertility in mice. Inactivation of c-mos results in abnormal oocyte development and leads to ovarian cysts and tumors in vivo. In contrast to the severe effects of c-mos ablation in females, targeted inactivation of c-mos has not been reported to affect spermatogenesis in male mice.