Interaction between major dietary patterns and cardiorespiratory fitness on metabolic syndrome in Iranian adults: a cross-sectional study.

BACKGROUND: Several researches have been conducted on the associations between diet and cardiorespiratory fitness (CRF) and major cardiovascular risk factors. However, there is no report about the interaction between major dietary patterns and CRF on metabolic syndrome (MetS) and its components. To investigate the combined association of major dietary patterns and CRF on MetS and its components. METHODS: This cross-sectional study was conducted on 270 apparently healthy adults living in Tehran, Iran. Dietary intake was evaluated using a validated food frequency questionnaire (FFQ). CRF was assessed using a graded exercise treadmill test. Socio-economic status, anthropometric measures, biochemical parameters, and blood pressure were evaluated according to standard methods. Major dietary patterns were identified by factor analysis. RESULTS: Three major identified dietary patterns were (healthy, mixed, and western). Significant positive association was found between mixed dietary pattern and metabolic syndrome (OR = 2.68, 95% CI (1.92,7.78), P = 0.04). There were not relations between tertiles of identified dietary patterns and remained outcomes. Those who had higher adherence to mixed pattern with also higher CRF showed a significant decrease for diastolic blood pressure (P < 0.01). Also we found that there was no significant interaction between any of dietary patterns and CRF on odds of MetS. CONCLUSIONS: Overall, adherence to mixed dietary pattern in this population was associated with increasing odds of MetS. However, nor CRF neither the combination of dietary patterns and CRF was related to the odds of MetS among Iranian adults. More studies are needed to clarify these associations and to consider interpersonal determinants.

Identification and characteristics of a novel Burkholderia strain with broad-spectrum antimicrobial activity.

A Burkholderia strain isolated from soil is capable of inhibiting the growth of bacteria, plant-pathogenic fungi, pathogenic yeasts, and protozoa. Inhibition does not involve cell contact or the presence of living cells, suggesting that at least a substantial portion of the antimicrobial activity is due to the excretion of extracellular compounds.

Expression of chalcone synthase and chalcone isomerase proteins in Arabidopsis seedlings.

Antibodies have been developed against the first two enzymes of flavonoid biosynthesis in Arabidopsis thaliana. Chalcone synthase (CHS) and chalcone isomerase (CHI) were overexpressed and purified from Escherichia coli as fusion proteins with glutathione S-transferase from Schistosoma japonicum. The recombinant proteins were then used to immunize chickens and the resulting IgY fraction was purified from egg yolks. Immunoblots of crude protein extracts from Arabidopsis seedlings carrying wild-type and null alleles for CHS and CHI showed that the resulting antibody preparations provide useful tools for characterizing expression of the flavonoid pathway at the protein level. An initial analysis of expression patterns in seedlings shows that CHS and CHI proteins are present at high levels during a brief period of early seedling germination that just precedes the transient accumulation of flavonoid end-products.

Are flavonoids synthesized by a multi-enzyme complex?

An enormous variety of metabolic processes are characterized by enzyme complexes, which are likely to play important roles in directing the efficient operation and specificity of cellular metabolism. In many cases membranes or cytoskeletal elements provide scaffolding for these highly ordered assemblies of enzymes. Biochemical and immunocytochemical studies indicate that the flavonoid biosynthetic pathway of higher plants involves a complex of sequentially-acting enzymes localized at the cytoplasmic face of the endoplasmic reticulum. This paper describes preliminary efforts to define the organization of this putative flavonoid biosynthetic complex and elucidate its role in controlling the synthesis of different flavonoid end-products in the model plant, Arabidopsis thaliana.

Bony and vascular anatomy of the normal cervical spine in the sheep.

STUDY DESIGN: This study analyzed the vascular and skeletal anatomy of the sheep cervical spine. It discusses the comparative anatomy of the cervical spine of sheep and humans. OBJECTIVES: To establish the suitability of the sheep model for studying the pathophysiology of traumatic and degenerative conditions of the cervical spine. SUMMARY OF BACKGROUND DATA: Many studies have attempted to evaluate the pathophysiology of spinal cord trauma, hypoxia, and variations in the local environment of the spinal cord using a variety of animal models. Few of the studies identified in an extensive literature review report or comment on the validity of these models regarding anatomy. METHODS: Techniques of macro- and micro-dissection and vascular casting with latex and methylmethacrylate were employed and the anatomy of sheep was compared with that of humans. RESULTS: On an anatomical basis, we found the sheep to be a suitable model for studying the pathophysiology of spinal cord trauma and disorders relative to humans. CONCLUSIONS: To properly assess the effect of various pathological processes on the spinal cord, an anatomically valid model is required. This study established that the sheep is a suitable animal model for studies of this type.

The glucose transporter GluT4 and secretory carrier membrane proteins (SCAMPs) colocalize in rat adipocytes and partially segregate during insulin stimulation.

Secretory carrier membrane proteins (SCAMPs) mark the recycling system for the insulin-responsive glucose transporter, GluT4, in rat adipocytes. Anti-GluT4 and anti-SCAMP antibodies each immunoadsorbed vesicles containing both antigens from a low density microsomal fraction that is enriched in both antigens. The immunoadsorbed vesicles also contain VAMPs (synaptobrevins), synaptic vesicle membrane proteins. All three antigens were colocalized in low density microsomal vesicles from both basal and insulin-stimulated adipocytes. The SCAMPs have the same electrophoretic mobility as a major polypeptides detected in GluT4 vesicles. During insulin stimulation, 40% each of GluT4 and VAMPs redistribute from low density microsomes to the plasma membrane fraction; however, < 10% of the SCAMPs redistribute. Immunocytochemical staining of adipose tissue shows almost complete coincidence of SCAMPs and GluT4 in the basal state and extensive redistribution of both antigens to the cell periphery during insulin stimulation. Segregation of antigens during stimulation is not as distinct as observed by fractionation, although there are regions at the cell border where the SCAMPs appear more concentrated than GluT4. These data suggest that during insulin stimulation, in contrast to the behaviour of GluT4, SCAMPs remain tightly associated with the recycling system.

Members of the VAMP family of synaptic vesicle proteins are components of glucose transporter-containing vesicles from rat adipocytes.

Existing data support the hypothesis that insulin triggers the exocytosis of small vesicles containing the GluT4 isoform of the glucose transporter. The data also suggest that these vesicles reform through endocytosis of GluT4. These processes resemble those described for synaptic vesicles after depolarization of nerve cells. To determine whether GluT4 vesicles are related to synaptic vesicles, rat adipocyte low density microsomes (LDM), which are rich in GluT4 vesicles, were screened for the synaptic vesicle proteins synaptotagmin, synaptophysin, SV2, p29, rab3, and VAMP (synaptobrevin) by immunoblotting. Two polypeptides that reacted with antibodies against the VAMPs were identified, one with the same apparent size as the two isoforms of VAMP in the brain (18 kDa) and one that was slightly smaller (17 kDa). These members of the VAMP family were highly enriched in GluT4 vesicles isolated by immunoadsorption and translocated from the LDM to the plasma membrane in response to insulin. With the exception of rab3, which was observed in the LDM but was not localized in the GluT4 vesicles, the other synaptic vesicle proteins were not detected. The presence of the VAMPs in both GluT4 and synaptic vesicles suggests that the genesis and/or exocytosis of these two types of vesicles involve shared processes.

Isolation by fluorescence-activated cell sorting of Chinese hamster ovary cell lines with pleiotropic, temperature-conditional defects in receptor recycling.

We have isolated several Chinese hamster ovary cell lines with temperature-sensitive defects in the recycling of receptors after endocytosis. These cell lines were selected using fluorescence-activated cell sorting for retention of a pulse of labeled transferrin after a chase in the presence of unlabeled transferrin. One of these cell lines, TfT1.11, was selected for further characterization. In TfT1.11 the trapping of transferrin within the cells is paralleled by a loss of cell surface transferrin receptors. Within 4 h after the shift from 33 to 41 degrees C the surface binding of transferrin is reduced to 18% of parental cells at 41 degrees C. The trapping of transferrin and the loss of transferrin receptor from the cell surface are caused by a temperature-conditional 5.5-fold decrease in the initial rate of transferrin recycling. TfT1.11 cells also rapidly lose 89% of their ability to take up alpha 2-macroglobulin after the temperature shift to 41 degrees C. These data indicate that the TfT1.11 cell line has a pleiotropic defect in receptor recycling.

Regulation of endocytic pH by the Na+,K+-ATPase in living cells.

Acidification of endocytosed ligands destined for lysosomes is biphasic, with a rapid drop to pH 6, followed by a slow decrease to pH 5. Continuous measurements of transferrin acidification have confirmed that the pH minimum in early (presorting) endosomes is approximately pH 6. On the basis of measurements of endosomal acidification in vitro, it has been proposed that the pH in the early endosome is limited by the internalization of the Na+,K+-ATPase, which generates an interior-positive membrane potential in this compartment [Fuchs, R., Schmid, S. & Mellman, I. (1989) Proc. Natl. Acad. Sci. USA 86, 539-543]. We present two lines of evidence that strongly implicate the Na+,K+-ATPase as a major regulatory element of endocytic pH in vivo. First, ouabain, a specific inhibitor of the Na+,K+-ATPase, interferes with the regulation of acidification in early endocytic compartments. Transferrin is normally rapidly acidified to pH 6.0-6.2, followed by alkalinization during recycling. In the presence of ouabain, the minimum pH of transferrin-containing endosomes decreases from 6.0-6.2 to less than 5.3. Second, ouabain eliminates the resistance to both the growth inhibitory and vacuologenic effects of chloroquine in the lysosomal acidification defective cell line CHL60-64. The phenotype of this cell line is consistent with a defect in the removal or inactivation of the early acidification regulatory elements from the late endocytic compartments. The ouabain data suggest that the defect in this cell line is due to improper localization of the Na+,K+-ATPase. A model for pH regulation and vacuolation by weak bases is discussed.

A chloroquine-resistant Swiss 3T3 cell line with a defect in late endocytic acidification.

To investigate the role of acidification in cell proliferation, several cell lines resistant to chloroquine were isolated with the expectation that some would express altered endocytic acidification. The preliminary characterization of one of these lines, CHL60-64, is described. In contrast to endocytic mutants described previously, the initial phase of endocytic acidification, as measured by transferrin acidification, is normal in this cell line. However, a difference in subsequent endocytic acidification was observed in CHL60-64. In the parental cells, internalized dextran was fully acidified to approximately pH 5.5 within 1 h. In CHL60-64, the pH in the endocytic compartment was only 6.1 after 1 h and remained as high as 5.8 for at least 4 h. After an 8-h incubation, the pH decreased to 5.5, indicating that the second phase of acidification is only slowed in CHL60-64, and not blocked. Consistent with this retarded acidification, ATP-dependent acidification in vitro (as measured by acridine orange accumulation) was reduced in both the lysosomal fraction and the endosomal fraction isolated from CHL60-64. A decrease in the in vivo rate of acridine orange accumulation after perturbation with amine was also observed. In addition to amine resistance and defective acidification, CHL60-64 was found to be resistant to vacuolation in the presence of chloroquine and ammonium chloride, and was resistant to ouabain. Further studies on this new class of endocytosis mutant, in combination with existing mutants, should help to clarify the mechanisms responsible for the regulation of endocytic acidification.

Growth inhibition of 3T3 fibroblasts by lysosomotropic amines: correlation with effects on intravesicular pH but not vacuolation.

The effects of five lysosomotropic amines on the growth of Swiss 3T3 fibroblasts were measured and compared with effects on intravesicular pH. Tributylamine and benzylamine, amines that affect intravesicular pH without causing vacuolation, were found to inhibit cell growth to a similar extent as vacuologenic amines previously tested. Excellent correlation between the half-maximal concentrations for the growth and pH effects were found for tributylamine, benzylamine, chloroquine, and ammonium chloride. The results suggest that growth inhibition by these amines is a direct result of their effects on pH and not due to other effects (such as vacuolation). In contrast, a 100-fold difference in the half-maximal concentrations was found for methylamine, suggesting that methylamine inhibits growth by a mechanism unrelated to pH.