On the role of mechanosensitive mechanisms eliciting reactive hyperemia

We hypothesized that changes in hemodynamic forces such as pressure (P) and flow (F) contribute importantly to the development of reactive hyperemia. To exclude the effects of vivo factors, isolated rat skeletal muscle arterioles ( approximately 130 microm) were utilized. We found that changes in P or P + F following occlusions elicited reactive dilations (RD). The peak of RD (up to approximately 45 microm), but not the duration of RD, increased to changes in P (80 to 10, then back to 80 mmHg) as a function of the length of occlusions (30, 60, and 120 s). However, changes in P + F (80-10 -80 mmHg + 25-0-25 microl/min) increased both the peak and duration of RD (from approximately 25 to 90 s) with longer occlusions. When only P changed, inhibition of nitric oxide synthesis or endothelium removal (E-) reduced only the peak of RD, whereas when P + F were changed, both the peak and duration of RD became reduced. Inhibition of stretch-activated cation channels by gadolinium reduced the peak but enhanced the duration of RD (both to P or P + F) that was unaffected by N(G)-nitro-l-arginine methyl ester (l-NAME) or by E-. When only P changed, inhibition of tyrosine kinases by genistein reduced peak RD but did not affect the RD duration. However, when P + F changed, genistein reduced both the peak and the duration of RD, additional l-NAME reduced the peak RD, but did not affect the duration of RD. Thus in isolated arterioles an RD resembling the characteristics of reactive hyperemia can be generated that is elicited by deformation, stretch, pressure, and flow/shear stress-sensitive mechanisms and is, in part, mediated by nitric oxide.     

Impaired spare respiratory capacity in cortical synaptosomes from Sod2 null mice

Presynaptic nerve terminals require high levels of ATP for the maintenance of synaptic function. Failure of synaptic mitochondria to generate adequate ATP has been implicated as a causative event preceding the loss of synaptic networks in neurodegenerative disease. Endogenous oxidative stress has often been postulated as an etiological basis for this pathology, but has been difficult to test in vivo. Inactivation of the superoxide dismutase gene (Sod2) encoding the chief defense enzyme against mitochondrial superoxide radicals results in neonatal lethality. However, intervention with an SOD mimetic extends the life span of this model and uncovers a neurodegenerative phenotype providing a unique model for the examination of in vivo oxidative stress. We present here studies on synaptic termini isolated from the frontal cortex of Sod2 null mice demonstrating impaired bioenergetic function as a result of mitochondrial oxidative stress. Cortical synaptosomes from Sod2 null mice demonstrate a severe decline in mitochondrial spare respiratory capacity in response to physiological demand induced by mitochondrial respiratory chain uncoupling with FCCP or by plasma membrane depolarization induced by 4-aminopyridine treatment. However, Sod2 null animals compensate for impaired oxidative metabolism in part by the Pasteur effect allowing for normal neurotransmitter release at the synapse, setting up a potentially detrimental energetic paradigm. The results of this study demonstrate that high-throughput respirometry is a facile method for analyzing specific regions of the brain in transgenic models and can uncover bioenergetic deficits in subcellular regions due to endogenous oxidative stress.     

GPR55 regulates cannabinoid 2 receptor-mediated responses in human neutrophils

The directional migration of neutrophils towards inflammatory mediators, such as chemokines and cannabinoids, occurs via the activation of seven transmembrane G protein coupled receptors (7TM/GPCRs) and is a highly organized process. A crucial role for controlling neutrophil migration has been ascribed to the cannabinoid CB(2) receptor (CB(2)R), but additional modulatory sites distinct from CB(2)R have recently been suggested to impact CB(2)R-mediated effector functions in neutrophils. Here, we provide evidence that the recently de-orphanized 7TM/GPCR GPR55 potently modulates CB(2)R-mediated responses. We show that GPR55 is expressed in human blood neutrophils and its activation augments the migratory response towards the CB(2)R agonist 2-arachidonoylglycerol (2-AG), while inhibiting neutrophil degranulation and reactive oxygen species (ROS) production. Using HEK293 and HL60 cell lines, along with primary neutrophils, we show that GPR55 and CB(2)R interfere with each other's signaling pathways at the level of small GTPases, such as Rac2 and Cdc42. This ultimately leads to cellular polarization and efficient migration as well as abrogation of degranulation and ROS formation in neutrophils. Therefore, GPR55 limits the tissue-injuring inflammatory responses mediated by CB(2)R, while it synergizes with CB(2)R in recruiting neutrophils to sites of inflammation.     

Comparison of 3 assay systems using a common probe substrate, calcein AM, for studying P-gp using a selected set of compounds

The multidrug resistance protein 1 (MDR1) transporter is the most abundantly investigated adenosine triphosphate (ATP)-Binding Cassette (ABC) transporter protein. Multiple assay systems were developed to study MDR1-mediated transport and possible drug-drug interactions. Yet, as different probe substrates are used in these assays, it is difficult to directly compare the results. In this study, a common probe substrate was applied in 3 assay systems developed to study MDR1: the cellular dye efflux assay, the ATPase assay, and the vesicular transport assay. This probe substrate is calcein acetoxymethyl ester (calcein AM), the acetoxymethyl ester derivative of the fluorescent dye, calcein. Using a common probe allows the investigation of the effect of passive permeability on the result obtained by testing various compounds. In this study, 22 compounds with different logP values were tested in the above-mentioned 3 assay systems. The vesicular transport assay proved most sensitive, detecting 18 of 22 interactions with the protein. The ATPase assay detected 15 interactions, whereas the cellular dye efflux assay was the least sensitive with only 10 hits. A correlation was found between the hydrophobicity of the compound and the ratio of cellular and vesicular transport IC(50) values, indicating the effect of passive permeability on the result. Based on hydrophobicity, the current study provides guidelines on applying the most correct tool for studying MDR1 interactions.     

A distinct sequence in the adenine nucleotide translocase from Artemia franciscana embryos is associated with insensitivity to bongkrekate and atypical effects of adenine nucleotides on Ca2+ uptake and sequestration

Mitochondria isolated from embryos of the crustacean Artemia franciscana lack the Ca(2+)-induced permeability transition pore. Although the composition of the pore described in mammalian mitochondria is unknown, the impacts of several effectors of the adenine nucleotide translocase (ANT) on pore opening are firmly established. Notably, ADP, ATP and bongkrekate delay, whereas carboxyatractyloside hastens, Ca(2+)-induced pore opening. Here, we report that adenine nucleotides decreased, whereas carboxyatractyloside increased, Ca(2+) uptake capacity in mitochondria isolated from Artemia embryos. Bongkrekate had no effect on either Ca(2+) uptake or ADP-ATP exchange rate. Transmission electron microscopy imaging of Ca(2+)-loaded Artemia mitochondria showed needle-like formations of electron-dense material in the absence of adenine nucleotides, and dot-like formations in the presence of adenine nucleotides or Mg(2+). Energy-filtered transmission electron microscopy showed the material to be rich in calcium and phosphorus. Sequencing of the Artemia mRNA coding for ANT revealed that it transcribes a protein with a stretch of amino acids in the 198-225 region with 48-56% similarity to those from other species, including the deletion of three amino acids in positions 211, 212 and 219. Mitochondria isolated from the liver of Xenopus laevis, in which the ANT shows similarity to that in Artemia except for the 198-225 amino acid region, demonstrated a Ca(2+)-induced bongkrekate-sensitive permeability transition pore, allowing the suggestion that this region of ANT may contain the binding site for bongkrekate.     

Drug localization in different lung cancer phenotypes by MALDI mass spectrometry imaging

Lung cancer is a common cause of cancer mortality in the world, largely due to the risk factor of tobacco smoking. The drug therapy at the molecular level includes targeting the epidermal growth factor receptor (EGFR) tyrosine kinase activity by using inhibitors, such as erlotinib (Tarceva) and gefitinib (Iressa). The heterogeneity of disease phenotypes and the somatic mutations presented in patient populations have a great impact on the efficacy of treatments using targeted personalized medicine. In this study, we report on basic physical and chemical properties of erlotinib and gefitinib in three different lung cancer tumor phenotypes, using MALDI instrumentation in imaging mode, providing spatial localization of drugs without chemical labeling. Erlotinib and gefitinib were analyzed in i) planocellular lung carcinoma, ii) adenocarcinoma and iii) large cell lung carcinoma following their deposition on the tissue surfaces by piezo-dispensing, using a controlled procedure. The importance of high-resolution sampling was crucial in order to accurately localize the EGFR tyrosine kinase inhibitors deposited in heterogeneous cancer tissue compartments. This is the first report on personalized drug characterization with localizations at a lateral resolution of 30μm, which allowed us to map these compounds at attomolar concentrations within the lung tumor tissue microenvironments.     

Bioinformatic strategies for unambiguous identification of prostate specific antigen in clinical samples

Prostate specific antigen (PSA), as a widely used clinical biomarker in prostate cancer diagnostics, exists in multiple molecular forms. However, all of these forms might not be recognized in a given sample by the standard immunoassays. Therefore, we have investigated PSA isoforms, separated by size, using mass spectrometric analyses. The objective of these developments was to identify and specify the various forms of PSA. To optimize successful identification of different PSA forms, we have developed a bioinformatic strategy, consisting of high resolution MALDI-MS PMF and sequencing MS/MS data searches. To improve sequence-based identification, the recently introduced Proteios software environment was employed, allowing the combination of multiple database search engines in an automated manner. We could unambiguously identify PSA in clinical samples by all detectable tryptic peptides, which were found to be common in several isoforms.