Monday, January 30, 2012

Copper tolerant yeast strains

Yeast strains endowed with robustness towards copper and/or enriched in intracellular Cu might find application in biotechnology processes, among others in the production of functional foods. Moreover, they can contribute to the study of human diseases related to impairments of copper metabolism. In this study, we investigated the molecular and physiological factors that confer copper tolerance to strains of baker's yeasts.
The study  characterized the effects elicited in natural strains of Candida humilis and Saccharomyces cerevisiae by the exposure to copper in the culture broth. We observed that, whereas the growth of Saccharomyces cells was inhibited already at low Cu concentration, C. humilis was naturally robust and tolerated up to 1 g * L-1 CuSO4 in the medium. This resistant strain accumulated over 7 mg of Cu per gram of biomass and escaped severe oxidative stress thanks to high constitutive levels of superoxide dismutase and catalase. Both yeasts were then "evolved" to obtain hyper-resistant cells able to proliferate in high copper medium. While in S. cerevisiae the evolution of robustness towards Cu was paralleled by the increase of antioxidative enzymes, these same activities decreased in evolved hyper-resistant Candida cells. We also characterized in some detail changes in the profile of copper binding proteins, that appeared to be modified by evolution but, again, in a different way in the two yeasts. Following evolution, both Candida and Saccharomyces cells were able to proliferate up to 2.5 g * L-1 CuSO4 and to accumulate high amounts of intracellular copper. The comparison of yeasts differing in their robustness, allowed highlighting physiological and molecular determinants of natural and acquired copper tolerance. We observed that different mechanisms contribute to confer metal tolerance: the control of copper uptake, changes in the levels of enzymes involved in oxidative stress response and changes in the copper-binding proteome. However, copper elicits different physiological and molecular reactions in yeasts with different backgrounds.

Eating probiotic bacteria can reduce behaviors associated with stress, anxiety and depression.

Probiotics are live microbial organisms that are naturally present in the digestive tract and vagina.

Probiotics are considered beneficial and are sometimes referred to as "friendly" bacteria. Some of the ways they are thought to promote health include suppressing the growth of potentially harmful bacteria, improving immune function, enhancing the protective barrier of the digestive tract, and helping to produce vitamin K.
There are over 400 species of microorganisms in the human digestive tract, including Lactobacillus and Bifidobacterium.

A number of medical, diet, and lifestyle factors are believed to disturb the balance in the colon. This imbalance is called dysbiosis. Factors include:
• Inadequate dietary fiber
• Oral antibiotic therapy
• Infant formula feeding
• Ingestion of environmental toxins
No longer kept in check, less healthy bacteria and yeast may flourish, which is thought to increase the likelihood of conditions such as infectious diarrhea and vaginal yeast infections.
Sources of Probiotics
Probiotics can be found in capsule, liquid, powder, or tablet form. Acidophilus drinks can be found in health food stores and some grocery stores and Asian grocers.

Probiotics can also be found in cultured dairy products such as yogurt or kefir, however, the number of live organisms varies greatly from product to product due to differences in processing methods. Fermented foods such as sauerkraut also contain probiotics.

Once ingested, probiotics colonize the intestines and other parts of the body and can sustain themselves unless they are destroyed by antibiotics or other factors.

Although they are thought to be essential for health, because they can sustain themselves in the body under normal circumstances, there is no recommended daily intake of probiotics.

Prebiotics
"Prebiotics" are also thought to improve the balance of probiotics in the intestines. They are non-digestible carbohydrates that stimulate the growth of beneficial bacteria in the intestines. Sources of prebiotics include fructo-oligosaccharides (FOS) and inulin, found in onions, asparagus, chicory, and banana. FOS is also available as a supplement and is sometimes combined with probiotic dietary supplements.

From guts to brains – eating probiotic bacteria changes behaviour in mice


From “gut feelings” to “having some guts”, English is full of phrases where our bowels exert an influence upon our behaviour. But these are more than metaphors. There are open lines of communication between brains and bowels and, in mice at least, these channels allow an individual’s gut bacteria to steer their behaviour.
The latest evidence for this “gut-brain axis” comes from Javier Bravo at University College Cork. He fed mice with a probiotic bacterium called Lactobacillus rhamnosus, often found in yoghurts and dairy products. The bacterial menu changed the levels of signalling chemicals in the rodents’ brains, and reduced behaviours associated with stress, anxiety and depression.
Probiotic bacteria – those that benefit their host – are the subject of sweeping, hand-waving health claims. But beneath the breathless marketing hype, there is some intriguing underlying science. For example, some trials have found that probiotics can help to alleviate the mood symptoms that accompany irritable bowel or chronic fatigue syndrome. To that end, Bravo wanted to see if L.rhamnosus could influence the brains of normal, healthy animals.
Bravo found that his mice, after regularly eating Lactobacillus, were more likely to spend time in the exposed parts of a maze (a common test for anxiety symptoms) than those who ate bacteria-free meals. They were also less likely to drift motionlessly when plopped into water (a common test for depressive symptoms). And during stressful situations, they built up lower levels of stress hormones.
The bacteria also boosted the role of GABA, a restraining chemical that downplays the buzzing of excitable neurons. GABA works by docking with receptor proteins, and Bravo found that Lactobacillus increased the numbers of these receptors in parts of the brain associated with learning, memory and emotional control. The GABA system is involved in several stress-related mental conditions. For example, animals with depressive symptoms have lower levels of GABA receptors in the front of their brains, and one group of anti-anxiety drugs works by enhancing the effects of GABA receptors in humans.
It may seem odd that bacteria in an animal’s gut can control what happens in its brain, on the other side of the body. But the two organs have a direct line between them – the long, branching vagus nerve, which transmits information from the gut and other visceral organs to the brain. When Bravo severed the vagus nerve in his mice, Lactobacillus lost all of its influence. It changed neither the rodents’ behaviour nor their GABA receptor levels.
Bravo’s study is the latest in an accumulating body of evidence showing that gut bacteria are little backseat drivers for their hosts. Earlier this year, I wrote about work from Rochellys Diaz Heijtz at the Karolinska Institute, who showed that germ-free mice without any gut bacteria behave differently to mice with a normal complement. They were more active, less anxious and more likely to take risks. And when Heijtz transplanted the gut bugs from normal mice into sterile babies, the recipients behaved in the usual cautious way when they grew up. A few months later, a Canadian team led by Karen-Anne Neufeld found similar results.
These studies showed that gut bacteria can affect the way a mouse’s brain develops at a young age, and Bravo expands upon them in two important ways. First, he showed that inoculations of Lactobacillus can change the behaviour of normal, healthy mice, as opposed to artificially sterile ones. Second, he showed that this works in adults, rather than just in babies.
The fact that doses of gut bacteria can change adult behaviour has important implications. John Cryan, who led the study, says, “It is highly plausible that probiotic agents in the future could be used to treat mood and anxiety disorders.” After all, his study has shown that these bacteria play around with the same brain chemicals in the brain that antidepressants and anti-anxiety drugs do.
This doesn’t mean that eating a lot of yoghurt will sort out a bout of depression. The idea of using gut bacteria to treat disorders isn’t far-fetched; after all, some doctors have already managed to treat people with gut infections by giving them “faecal transplants”. However, when it comes to the brain, the science is still in its early days.
Bravo still doesn’t know how the bacteria use the vagus nerve to influence the brain, only that they do. Nor does he know how long the effects on GABA and behaviour would last, or how the microbes affect other chemical signals within the brain. And critically, all of these experiments have been done in mice. No one knows if the same thing applies to humans.
“We have no reason to expect that the same would not apply to humans,” says Cryan. “However, such clinical studies need to be carried out.” However, he cautions that not all probiotics do the same thing and he warns against overinterpreting the results of the study.

Friday, January 27, 2012

Omega-3 for your beauty and health


Omega-3 for your beauty and health
Fatty acids known as "omega-3" as the fat is unsaturated and remaining liquid even after putting them in the refrigerator or when exposed to freezing.

Omega-3 differ from olive oil which is single non-fat saturation remain liquid under room temperature, but it freezes if you put in the refrigerator, preferably eating all of these types of oils to maintain our health.
The body needs two types of fats: multiple unsaturated omega-3(alpha-linoleic) and omega-6 (linoleic). Because the body cannot manufacturing these types of fats ;we must take these two types of fatty acids from food.
Few people suffer from a lack of omega-6; because it is available in corn oil, sunflower oil, canola oil, soy, as it is available a large amount in the tissues of animals such as; beef and chicken. And excessive consumption of meat leads to the high proportion of omega 6 to omega-3 leads to health problems. One of the characteristics of omega-6 that promotes inflammation and maintains it, and omega-3 anti-inflammatory and helps healing.

 
The salmon, flaxseed, and walnuts are excellent sources of omega-3 material and then sardines, soya beans and cooked prawns grilled or boiled, and fatty fish such as; mackerel, herring and tuna. The researchers stressed that foods rich in omega-3 absorbed by the body faster than fish oil capsule. They also stressed that eating fish rich in omega-3 twice a week can raise the level of these fats in the body.
Newly in markets there are eggs rich in omega-3; where flaxseed is added to the chicken food, the chicken eggs becomes rich in omega-3. And thus gives eggs fortified 25-30% of the needs of omega-3. As for the consumption of eggs, it can take up to 5 eggs a week, except in cases of severe hereditary high cholesterol.
If you suffer from cardiovascular disease, diabetes type II, extreme fatigue, dry skin, inability to concentrate or joint pain, you need foods rich in omega-3; as these fats reduces the risk of diabetes type II, as it strengthens hair, nails and make the skin smoothfatty acids omega-3 Play role in reducing inflammation, and prevent cardiovascular disease and reduce the risk of heart attack, high blood pressure and triglycerides and bad cholesterol, and improves the body's response to insulin, strengthens the immune system response against infection, such as; arthritis, lupus, asthma, as well as inhibit the growth of cancer cells, especially breast cancer must therefore consumption of prevention.
The researchers stressed that the diet that contains large amounts of saturated fat and hydrogenated lead to thickening of cell membranes what causes the loss of cells of essential nutrients and water, causing non-contact cells with each other and this dysfunction can lead to the growth of cancerous tumors in some people, while diet rich omega-3 fats make cell membranes more fluid and contact cells better which preserve the health of the cell
modern medical research advised of the importance of dealt with amino acids and the "Omega 3" and fish oil for the prevention of osteoporosis or slow rates of evolution among his patients.
Research has shown that eating omega -3 working on the prevention of osteoporosis at a rate 30 times the other nutrients.
The oils, fats, including fats, omega-3 damaged when exposed to heat or light or oxygen (air) for a long time, where the oxidized fatty acid or rancidify oil and changing taste and smell, and thus less nutritional value and can lead to cancers and other diseases.
Flax seeds contain the essential oils, it is advisable to save it in a sealed container and place it in the refrigerator or freezer
An overdose of omega-3 fatty acid can reduce blood pressure and liqify the blood, so patients should consult the doctor before taking fish oil pills rich in omega-3.
Dietary supplements that contain omega-3 either material made of Flax seeds oil or fish liver oil, and preferably from organic products are kept in glass vials of green or dark brown and make sure save valuable refrigerator or freeze.

The national health organization advises of eating 120 grams of grilled fish, especially salmon and herring twice a week to increase the rate of omega-3 in the body or eating two tablespoons of food linseed addition to 120 grams of salmon grilled in a week and a vegetarian recommends an increase in eating walnuts and flaxseed
Pregnant and lactating women and children needs Omega 3 for the effective functioning of the brain and cells, as well as people with Alzheimer's, asthma, cancer, heart disease, diabetes, eczema, high blood pressure, migraine, obesity, multiple sclerosis, osteoporosis, arthritis, and other