Effect of weight loss and exercise on angiogenic factors in the circulation and in adipose tissue in obese subjects

Background:

Vascular growth is a prerequisite for adipose tissue (AT) development and expansion. Some AT cytokines and hormones have effects on vascular development, like vascular endothelial growth factor (VEGF‐A), angiopoietin (ANG‐1), ANG‐2 and angiopoietin‐like protein‐4 (ANGPTL‐4).

Methods:

In this study, the independent and combined effects of diet‐induced weight loss and exercise on AT gene expression and proteins levels of those angiogenic factors were investigated. Seventy‐nine obese males and females were randomized to: 1. Exercise‐only (EXO; 12‐weeks exercise without diet‐restriction), 2. Hypocaloric diet (DIO; 8‐weeks very low energy diet (VLED) + 4‐weeks weight maintenance diet) and 3. Hypocaloric diet and exercise (DEX; 8‐weeks VLED + 4‐weeks weight maintenance diet combined with exercise throughout the 12 weeks). Blood samples and fat biopsies were taken before and after the intervention.

Results:

Weight loss was 3.5 kg in the EXO group and 12.3 kg in the DIO and DEX groups. VEGF‐A protein was non‐significantly reduced in the weight loss groups. ANG‐1 protein levels were significantly reduced 22‐25% after all three interventions (P < 0.01). The ANG‐1/ANG‐2 ratio was also decreased in all three groups (P < 0.05) by 27‐38%. ANGPTL‐4 was increased in the EXO group (15%, P < 0.05) and 9% (P < 0.05) in the DIO group. VEGF‐A, ANG‐1, and ANGPTL‐4 were all expressed in human AT, but only ANGPTL‐4 was influenced by the interventions.

Conclusions:

Our data show that serum VEGF‐A, ANG‐1, ANG‐2, and ANGPTL‐4 levels are influenced by weight changes, indicating the involvement of these factors in the obese state. Moreover, it was found that weight loss generally was associated with a reduced angiogenic activity in the circulation.     

HOIL-1 is not required for iron-mediated IRP2 degradation in HEK293 cells

Iron regulatory protein 2 (IRP2) binds to iron-responsive elements (IREs) to regulate the translation and stability of mRNAs encoding several proteins involved in mammalian iron homeostasis. Increases in cellular iron stimulate the polyubiquitylation and proteasomal degradation of IRP2. One study has suggested that haem-oxidized IRP2 ubiquitin ligase-1 (HOIL-1) binds to a unique 73-amino acid (aa) domain in IRP2 in an iron-dependent manner to regulate IRP2 polyubiquitylation and degradation. Other studies have questioned the role of the 73-aa domain in iron-dependent IRP2 degradation. We investigated the potential role of HOIL-1 in the iron-mediated degradation of IRP2 in human embryonic kidney 293 (HEK293) cells. We found that transiently expressed HOIL-1 and IRP2 interact via the 73-aa domain, but this interaction is not iron-dependent, nor does it enhance the rate of IRP2 degradation by iron. In addition, stable expression of HOIL-1 does not alter the iron-dependent degradation or RNA-binding activity of endogenous IRP2. Reduction of endogenous HOIL-1 by siRNA has no affect on the iron-mediated degradation of endogenous IRP2. These data demonstrate that HOIL-1 is not required for iron-dependent degradation of IRP2 in HEK293 cells, and suggest that a HOIL-1 independent mechanism is used for IRP2 degradation in most cell types.     

Regulation of Mitochondrial Iron Import through Differential Turnover of Mitoferrin 1 and Mitoferrin 2

Mitoferrin 1 and mitoferrin 2 are homologous members of the mitochondrial solute carrier family. Mitoferrin 1 is required for mitochondrial iron delivery in developing erythrocytes. Here we show that mitoferrin 1 and mitoferrin 2 contribute to mitochondrial iron delivery in a variety of cells. Reductions in mitoferrin 1 and/or mitoferrin 2 levels by RNA interference result in decreased mitochondrial iron accumulation, heme synthesis, and iron-sulfur cluster synthesis. The ectopic expression of mitoferrin 1 in nonerythroid cells silenced for mitoferrin 2 or the expression of mitoferrin 2 in cells silenced for mitoferrin 1 restored heme synthesis to “baseline” levels. The ectopic expression of mitoferrin 2, however, did not support hemoglobinization in erythroid cells deficient in mitoferrin 1. Mitoferrin 2 could not restore heme synthesis in developing erythroid cells because of an inability of the protein to accumulate in mitochondria. The half-life of mitoferrin 1 was increased in developing erythroid cells, while the half-life of mitoferrin 2 did not change. These results suggest that mitochondrial iron accumulation is tightly regulated and that controlling mitoferrin levels within the mitochondrial membrane provides a mechanism to regulate mitochondrial iron levels.Iron is a required element for all eukaryotes, but iron can be toxic at high concentrations. Consequently, the cellular acquisition of iron is highly regulated, as is the concentration of free iron in biological fluids. The regulation of iron concentration is extended to cellular organelles that either store or utilize iron. Mitochondria utilize iron for the synthesis of heme and iron-sulfur (Fe-S) clusters. These prosthetic groups are used within the mitochondria and are exported for use by cytosolic and nuclear proteins. The mechanisms that regulate mitochondrial iron levels are not known, although it is clear that mitochondrial iron levels must be regulated. For example, the loss of function mutations in genes that encode enzymes required for Fe-S cluster synthesis or the Atm1 transporter that exports Fe-S clusters, results in excessive mitochondrial iron accumulation in yeast and humans (for a review, see reference 11).The mechanisms that regulate mitochondrial iron pools are not well defined. Mitochondrial iron pools might be regulated at the level of import. Mitoferrin 1 (Mfrn1) has been shown to be required for mitochondrial iron import in developing erythroid cells. A mutation in zebrafish Mfrn1 (frascati) or the deletion of mouse Mfrn1 leads to defects in hemoglobinization due to a deficit in mitochondrial iron uptake (17). The phenotype of frascati zebrafish is restricted to developing red blood cells; other cell types showed no evidence of a mitochondrial iron phenotype. Mfrn1 has a paralogue, Mfrn2, and both genes have homologues MRS3 and MRS4 in Saccharomyces cerevisiae. Yeast with deletions of MRS3 and MRS4 grows poorly under low iron conditions due to impaired mitochondrial iron acquisition (5, 10, 13, 23). In yeast, the expression of Mfrn1 or Mfrn2 in Δmrs3 Δmrs4 cells can correct the poor growth under low iron conditions. The expression of either mouse or zebrafish Mfrn1 as a transgene in frascati zebrafish corrected the hemoglobin deficiency in cells, but the expression of Mfrn2 did not (17). These observations raise three questions. (i) What is the role of Mfrn2 in mitochondrial iron metabolism? (ii) Is iron transport into mitochondria regulated? (iii) If Mfrn2 transports iron into the mitochondria of vertebrate cells, why doesn''t Mfrn2 rescue the mitochondrial defect in Mfrn1-deficient zebrafish?Here, we show that Mfrn1 and Mfrn2 can transport iron into the mammalian mitochondria of nonerythroid cells. The ectopic expression of either Mfrn1 or Mfrn2 can restore mitochondrial iron transport in cells silenced for Mfrn2 and -1, respectively, but ectopic expression has little effect on increasing mitochondrial iron levels above the baseline values. Mitochondrial iron levels do not increase over the baseline because the levels of Mfrns are regulated posttranslationally. Mfrn1 accumulates in the mitochondria of developing red blood cells as a result of an increased protein half-life. In contrast, Mfrn2 does not accumulate in developing red blood cells or other cells, as the half-life of Mfrn2 protein remains constant.     

Iron and iron/manganese ratio in forage from Icelandic sheep farms: relation to scrapie

This study was undertaken in order to examine whether any connection existed between the amounts of iron in forage and the sporadic occurrence of scrapie observed in certain parts of Iceland. As iron and manganese are considered antagonistic in plants, calculation of the Fe/Mn ratios was also included by using results from Mn determination earlier performed in the same samples. Forage samples (n = 170) from the summer harvests of 2001–2003, were collected from 47 farms for iron and manganese analysis. The farms were divided into four categories: 1. Scrapie-free farms in scrapie-free areas (n = 9); 2. Scrapie-free farms in scrapie-afflicted areas (n = 17); 3. Scrapie-prone farms (earlier scrapie-afflicted, restocked farms) (n = 12); 4. Scrapie-afflicted farms (n = 9). Farms in categories 1 and 2 are collectively referred to as scrapie-free farms. The mean iron concentration in forage samples from scrapie-afflicted farms was significantly higher than in forage samples from farms in the other scrapie categories (P = 0.001). The mean Fe/Mn ratio in forage from scrapie-afflicted farms was significantly higher than in forage from scrapie-free and scrapie-prone farms (P < 0.001). The results indicated relative dominance of iron over manganese in forage from scrapie-afflicted farms as compared to farms in the other categories. Thus thorough knowledge of iron, along with manganese, in soil and vegetation on sheep farms could be a pivot in studies on sporadic scrapie.     

Cytosolic aconitase and ferritin are regulated by iron in Caenorhabditis elegans

Iron regulatory protein-1 (IRP-1) is a cytosolic RNA-binding protein that is a regulator of iron homeostasis in mammalian cells. IRP-1 binds to RNA structures, known as iron-responsive elements, located in the untranslated regions of specific mRNAs, and it regulates the translation or stability of these mRNAs. Iron regulates IRP-1 activity by converting it from an RNA-binding apoprotein into a [4Fe-4S] cluster protein exhibiting aconitase activity. IRP-1 is widely found in prokaryotes and eukaryotes. Here, we report the biochemical characterization and regulation of an IRP-1 homolog in Caenorhabditis elegans (GEI-22/ACO-1). GEI-22/ACO-1 is expressed in the cytosol of cells of the hypodermis and the intestine. Like mammalian IRP-1/aconitases, GEI-22/ACO-1 exhibits aconitase activity and is post-translationally regulated by iron. Although GEI-22/ACO-1 shares striking resemblance to mammalian IRP-1, it fails to bind RNA. This is consistent with the lack of iron-responsive elements in the C. elegans ferritin genes, ftn-1 and ftn-2. While mammalian ferritin H and L mRNAs are translationally regulated by iron, the amounts of C. elegans ftn-1 and ftn-2 mRNAs are increased by iron and decreased by iron chelation. Excess iron did not significantly alter worm development but did shorten their life span. These studies indicated that iron homeostasis in C. elegans shares some similarities with those of vertebrates.     

Scanning electron microscopy and gramicidin patch clamp recordings of microvillous receptor neurons dissociated from the rat vomeronasal organ

Vomeronasal organs from female rats were dissociated and isolated microvillous receptor neurons were studied. The isolated receptor neurons kept the typical bipolar shape which they have in situ as observed by scanning electron microscopy. We applied the perforated patch-clamp technique using the cation-selective ionophore gramicidin on freshly isolated and well differentiated receptor neurons. The mean resting potential was -58+/-14 mV (n=39). The contribution of the sodium pump current to the resting potential was demonstrated by lowering the K+ concentration in the bath or by application of 100 microM dihydro-ouabain. The input resistance was in the range of 1-6 GOmega and depolarizing current pulses of a few pA were sufficient to trigger overshooting action potentials. In voltage clamp conditions a fast transient sodium inward current and a sustained outward potassium current were activated by membrane depolarization. These observations indicate that freshly isolated vomeronasal receptor neurons of rats can be recorded, using gramicidin, with little modification of the intracellular content. Their electrophysiological properties are very similar to those observed in situ. Four out of eight female vomeronasal receptor cells were depolarized by diluted rat male urine.