Finding protection from tumor growth in unexpected places

As just about anyone who takes even the simplest medications knows, almost everything has side-effects. Generally, theres no free lunch. The aspirin that reduces your fever and (maybe) makes your hangover a little less painful can also cause ulcers and stomach bleeding.

Among the many thousands of proteins, hormones, enzymes, and the like that are active naturally in your body at any one time, most presumably are there for a beneficial purpose. But not always. Some have a distinct Jekyll/Hyde quality about them.

Consider, in particular, the hormone known as angiotensin II. It is part of what is called the renin-angiotensin system, which helps regulate blood pressure. Overlooking a number of details, one of the key functions of angiotensin II is to quickly constrict blood vessels, to minimize blood loss in the event of serious injury. However, because it raises blood pressure, the body needs for it not to be around most of the time, to avoid dangerous hypertension.

The way the body handles this is by producing a slightly different hormone instead, angiotensin I, which can be quickly converted, when required, into angiotensin II by means of an enzyme called simply angiotensin-converting enzyme (ACE). Its ACE were really here to talk about in this note, because it appears to have several other functions besides the one its named for. Ironically, one of the strategies for treating hypertension is to inhibit ACE, because of the need to keep blood pressure under control. Yet some of its side effects, unrelated to blood pressure, seem beneficial.

Finding Protection From Tumor Growth In Unexpected Places

Researchers have discovered that an enzyme commonly involved in regulating blood pressure also provides protection from tumor growth when strongly expressed in immune cells.

ACE, in fact, is involved in a surprising number of other processes in addition to restraining tumor gowth via its immune system activity.

Angiotensin-converting enzyme (ACE) plays a direct role in controlling blood pressure and is a common therapeutic target in hypertension. However, it also plays roles in such diverse processes as fertility, immune cell development, and atherosclerosis, and a few studies have even suggested a role for ACE in generating an effective immune response.

The researchers used experimental mice (ACE 10/10 mice) that express ACE only in their macrophages. The findings were quite intriguing.

When injected with aggressive melanoma cells, normal mice developed large melanoma tumors whereas ACE 10/10 mice developed only very small tumors. The resistance of ACE 10/10 mice to melanoma growth was confirmed using several different melanoma cell lines and by using different strains of mice expressing high levels of ACE in macrophages. Interestingly, the small tumors of ACE 10/10 mice contained significantly higher numbers of white blood cells, suggesting a large anti-tumor immune response.

To confirm the existence of an ACE-specific anti-tumor immune response, normal mice were depleted of their bone marrow and transplanted with ACE 10/10 bone marrow. When the transplanted normal mice were then injected with melanoma cells, they too were able to control tumor growth. The immune response involved not just the ACE-expressing macrophages but also increased numbers of cytotoxic T cells and levels of immune-activating chemicals and decreased levels of immune-suppressing chemicals. Finally, the ACE 10/10 macrophages alone could direct the immune response and convey protection as direct injection of these cells into melanoma tumors of normal mice yielded decreased tumor size.

It will be very interesting to learn what further research reveals about how ACE enhances the immune system.

Tags: angiotensin-converting enzyme, cancer, immune system

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Rare Earths From The Ocean

The SMH reports that Japanese researchers have found large rare earth deposits on the bottom of the Pacific Ocean (the plan to perform acid leaching at sea doesn’t sound very environmentally friendly though) - Rare earth deposits used to make iPads found in ocean.

Vast deposits of rare earth minerals, crucial in making high-tech electronics products, have been found on the floor of the Pacific Ocean and can be readily extracted, Japanese scientists said. … The discovery was made by a team led by Kato and including researchers from the Japan Agency for Marine-Earth Science and Technology.

They found the minerals in sea mud extracted from depths of 3500 to 6000 metres below the ocean surface at 78 locations. One-third of the sites yielded rich contents of rare earths and the metal yttrium, Kato said in a telephone interview. The deposits are in international waters in an area stretching east and west of Hawaii, as well as east of Tahiti in French Polynesia, he said.

He estimated rare earths contained in the deposits amounted to 80 to 100 billion tonnes, compared to global reserves currently confirmed by the US Geological Survey of just 110 million tonnes that have been found mainly in China, Russia and other former Soviet countries, and the United States.

The level of uranium and thorium - radioactive ingredients that are usually contained in such deposits that can pose environmental hazards - was found to be one-fifth of those in deposits on land, Kato said.

A chronic shortage of rare earths, vital for making a range of high-technology electronics, magnets and batteries, has encouraged mining projects for them in recent years. China, which accounts for 97 per cent of global rare earth supplies, has been tightening trade in the strategic metals, sparking an explosion in prices.

Japan, which accounts for a third of global demand, has been stung badly, and has been looking to diversify its supply sources, particularly of heavy rare earths such as dysprosium used in magnets.

Kato said the sea mud was especially rich in heavier rare earths such as gadolinium, lutetium, terbium and dysprosium. ...

Extracting the deposits requires pumping up material from the ocean floor. "Sea mud can be brought up to ships and we can extract rare earths right there using simple acid leaching," he said. "Using diluted acid, the process is fast, and within a few hours we can extract 80-90 per cent of rare earths from the mud."

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Black Hole Outflows From Centaurus A

Black Hole Outflows From Centaurus A

This image of Centaurus A shows a spectacular new view of a supermassive black holes power. Jets and lobes powered by the central black hole in this nearby galaxy are shown by submillimeter data (colored orange) from the Atacama Pathfinder Experiment (APEX) telescope in Chile and X-ray data (colored blue) from the Chandra X-ray Observatory. Visible light data from the Wide Field Imager on the Max-Planck/ESO 2.2 m telescope, also located in Chile, shows the dust lane in the galaxy and background stars. The X-ray jet in the upper left extends for about 13,000 light years away from the black hole. The APEX data shows that material in the jet is travelling at about half the speed of light.

Centaurus A – click for 665×505 image


Additional information:

Black Hole Outflows From Centaurus A (1/28/09)

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Battery Storage Could Get a Huge Boost from Seaweed

Technology Review has an article on a possible technique for greatly improving the performance of lithium-ion batteries - Battery Storage Could Get a Huge Boost from Seaweed

Lithium-ion batteries could hold up to 10 times as much energy per cell if silicon anodes were used instead of graphite ones. But manufacturers dont use silicon because such anodes degrade quickly as the battery is charged and discharged.

Researchers at the Georgia Institute of Technology and Clemson University think they might have found the ingredient that will make silicon anodes work—a common binding agent and food additive derived from algae and used in many household products. They say this material could not only make lithium-ion batteries more efficient, but also cleaner and cheaper to manufacture.
Lithium-ion batteries store energy by accumulating ions at the anode; during use, these ions migrate, via an electrolyte, to the cathode. The anodes are typically made by mixing an electroactive graphite powder with a polymer binder—typically polyvinylidene fluoride (PVDF)—dissolved in a solvent called NMP. The resulting slurry is spread on the metal foil used to collect electrical current, and dried.

If silicon particles are used as the basis of the electroactive powder, the batterys anode can hold more ions. But silicon particles swell as the battery is charged, increasing in volume up to four times their original size. This swelling causes cracks in the PVDF binder, damaging the anode. In research published today by Science, the Georgia Tech and Clemson scientists show that when alginate is used instead of PVDF, the anode can swell and the binder wont crack. This allows researchers to create a stable silicon anode that has, so far, been demonstrated to have eight times the capacity of the best graphite-based

The polymer alginate is made from brown algae, including the type which forms forests of giant kelp. It is already widely used as a gelling agent and a food additive. Initially, the researchers thought to replace PVDF with a combination of several different materials. Then, on theoretical grounds, they realized that a polymer with just the right kind of uniform structure could do all the things the binder was supposed to do, including providing good structural support while not chemically reacting with the electrolyte.

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From pit to port Indias 10bn coal export plan

The Australian has a look at an Indian corporations plan to vertically integrate power consumption starting from Queenslands coal fields - From pit to port: Indias $10bn coal export plan. When I read stories like this I tend to think averting serious global warming problems really isnt going to be easy...

INDIAN energy giant Adani Enterprises has moved foreign investment in Australia to a new level, with a $10 billion scheme to control every stage of its booming coal export business from mine to port.



In his first major interview, the chief executive of Adanis Australian operations, Jignesh Derasari, declared the company wanted to control "whatever component the coal touches", including a $3bn railway network to haul coal from the emergent Galilee Basin in central Queensland to two ports, one of which it purchased this year and the other which it will build at Dudgeon Point near Mackay.



From these outlets, Adani-owned bulk carriers would ship the coal to India to supply a chain of seven power stations operated by the company.



The scheme is one of the most ambitious vertically integrated resource developments ever proposed in Australia and comes after the federal government rejected bids by Chinese concerns to set up mine-to-port iron ore operations in Western Australia. It will make Adani Indias largest single investor in this country.



The massive mine is being developed in the Galilee Basin about 400km inland of Mackay, Australias new coal frontier, where Gina Rineharts Hancock Prospecting and Clive Palmers Waratah Holdings are also pursuing major developments.



Hancock Prospecting is in negotiations with Indian company GVK to sell its holdings in the area for $2bn, while Waratah has a contract to sell 30 million tonnes of coal to China over the next 20 years.



Mr Derasaris candid admission that Adani wants to control the production chain at every level from the Galilee Basin adds another dimension to the intensifying row between coal and coal-seam gas developers and farmers over land access. NSW Premier Barry OFarrell bought into this yesterday, saying he respected "the fact that there are parts of our state which should and always will be kept as agriculture".



Mr Derasari told The Weekend Australian that vertigal integration was central to the companys development plan in the Galilee. "Whatever component the coal touches, we would like to be in control of that," he said. "So that means the mine, the rail, the port where the coal is transported out of, the ship that the coal sits on until it gets to the port in India. Then it goes on a conveyer belt to the power station."

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45bn coal seam gas projects draw workers from around the world

The Australian has an article on the windfall heading Bechtel’s way as construction looms for 3 coal seam gas LNG projects in Queensland - $45bn gas plan draws workers of the world.

WORKERS from as far away as Ireland will be part of the massive fly-in, fly-out workforce needed to build the $45 billion development turning coal-seam gas into liquified natural gas on Curtis Island off Gladstone, central Queensland.
About 800 people are now working on the mangrove-fringed island on the north side of Gladstone Harbour, but this is expected to rise to at least 6000, housed in specially constructed camps, within two years. There will also be up to 2000 contractors, who will not live on site but will be ferried across from Gladstone every day to help build the three liquid natural gas plants, expected to be operating by 2015.

While protests against coal-seam gas continue in areas such as the Darling Downs, where 40,000 coal-seam wells will be constructed, the export industry is proceeding rapidly. The pipeline that carries the coal-seam gas from the Darling Downs to Gladstone is under construction, and work on the plants that will convert the gas into 38 million tonnes of liquid to be exported to Asia each year is well under way.

Three LNG plants are being built -- by the British-owned BG Group, Santos and Origin -- but all three $15bn plants are being built by US construction giant Bechtel, which owns the intellectual property rights to the technology. Bechtel, one of the worlds biggest contractors with a global workforce of 55,000, is already a big employer in Gladstone, with about 1500 people working at the expansion of Rio Tintos alumina refinery at Yarwun. …

The sheer scale of the three projects is having a debilitating effect on the central Queensland region, already suffering a skills shortage because of the mining boom. While wages for unskilled workers in mining average between $80,000 and $120,000 a year, with up to $150,000 for more skilled workers, labour hire operators estimate the short-term nature and urgency of the jobs on Curtis Island mean the pay on offer is 15-20 per cent higher than in mining industries. ... A mine worker paid $150,000 a year might be able to get $180,000 as the Curtis Island workforce increases.

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3 D Printer Company Seizes Machine From Desktop Gunsmith

Wired reports on a new form of printcrime, with one - 3-D Printer Company Seizes Machine From Desktop Gunsmith.

Cody Wilson planned in the coming weeks to make and test a 3-D printed pistol. Now those plans have been put on hold as desktop-manufacturing company Stratasys pulled the lease on a printer rented out for Wiki Weapon, the internet project lead by Wilson and dedicated to sharing open-source blueprints for 3-D printed guns. Stratasys even sent a team to seize the printer from Wilson’s home.

“They came for it straight up,” Cody Wilson, director of Defense Distributed, the online collective that oversees the Wiki project, tells Danger Room. “I didn’t even have it out of the box.” Wilson, who is a second-year law student at the University of Texas at Austin, had leased the printer earlier in September after his group raised $20,000 online. As well as using the funds to build a pistol, the Wiki Weapon project aimed to eventually provide a platform for anyone to share 3-D weapons schematics online. Eventually, the group hoped, anyone could download the open source blueprints and build weapons at home.

Until Stratasys pulled the lease, the Wiki Weapon project intended to make a fully 3-D printed pistol for the first time, though it would likely be capable of only firing a single shot until the barrel melted. Still, that would go further than the partly plastic AR-15 rifle produced by blogger and gunsmith Michael Guslick. Also known as “Have Blue,” Guslick became an online sensation after he made a working rifle by printing a lower receiver and combining it with off-the-shelf metal parts.

But last Wednesday, less than a week after receiving the printer, Wilson received an e-mail from Stratasys: The company wanted its printer returned. Wilson wrote back, and said he believed using the printer to manufacture a firearm would not break federal laws regarding at-home weapons manufacturing. For one, the gun wouldn’t be for sale. Wilson added that he didn’t have a firearms manufacturers license.

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