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kottke.org posts about biology

The trees of Chernobyl

This is what the trees look like near Chernobyl when you cut them down. It’s a biiiit tricky but see if you can spot when the nuclear plant disaster happened…

Chernobyl trees

Not surprisingly, researchers have found evidence that the radiation has affected the growth of trees near the accident site. From the paper:

Mean growth rate was severely depressed and more variable in 1987-1989 and several other subsequent years, following the nuclear accident in April 1986 compared to the situation before 1986. The higher frequency of years with poor growth after 1986 was not caused by elevated temperature, drought or their interactions with background radiation. Elevated temperatures suppressed individual growth rates in particular years. Finally, the negative effects of radioactive contaminants were particularly pronounced in smaller trees. These findings suggest that radiation has suppressed growth rates of pines in Chernobyl, and that radiation interacts with other environmental factors and phenotypic traits of plants to influence their growth trajectories in complex ways.


Liquid mammoth blood found

A mammoth recently found in Siberia was so well preserved that when researchers were chipping it out of the ice, liquid blood flowed out.

Semyon Grigoriev, chairman of the university’s Museum of Mammoths and head of the expedition, said: “The fragments of muscle tissues, which we’ve found out of the body, have a natural red colour of fresh meat. The reason for such preservation is that the lower part of the body was underlying (sic) in pure ice, and the upper part was found in the middle of tundra. We found a trunk separately from the body, which is the worst-preserved part.”

The temperature was ten degrees celsius below zero when the mammoth was found, so the discovery of liquid blood was a shock. “It can be assumed that the blood of mammoths had some cryo-protective properties,” Grigoriev said. “The blood is very dark, it was found in ice cavities below the belly and when we broke these cavities with a pick, the blood came running out.”

More photos and information here. Bring on the mammoth clones, John Hammond. (via @carlzimmer)


Bees still dying at a fantastic rate

Despite progress in recent years on causes and cures, colony collapse disorder has wreaked havoc on honeybee colonies across the country.

A mysterious malady that has been killing honeybees en masse for several years appears to have expanded drastically in the last year, commercial beekeepers say, wiping out 40 percent or even 50 percent of the hives needed to pollinate many of the nation’s fruits and vegetables.

Which is like, yeah, big whoop, it’s just bees, right? Except that:

The Agriculture Department says a quarter of the American diet, from apples to cherries to watermelons to onions, depends on pollination by honeybees.


Possible fossils found in meteorite fragments?

Well, here’s something potentially interesting: researchers at Cardiff University think they have found fossils in meteorite fragments from Sri Lanka.

The most startling claims, however, are based on electron microscope images of structures within the stones (see above). Wallis and co say that one image shows a complex, thick-walled, carbon-rich microfossil about 100 micrometres across that bares similarities with a group of largely extinct marine dinoflagellate algae.

They say another image shows well-preserved flagella that are 2 micrometres in diameter and 100 micrometres long. By terrestrial standards, that’s extremely long and thin, which Wallis and co interpret as evidence of formation in a low-gravity, low-pressure environment.

Gotta take this with a massive grain of salt, but it will be interesting to see how this one plays out.

Update: One of the authors of this study holds some unusual views about life on Earth.

On May 24, 2003 The Lancet published a letter from Wickramasinghe, jointly signed by Milton Wainwright and Jayant Narlikar, in which they hypothesized that the virus that causes Severe Acute Respiratory Syndrome (SARS) could be extraterrestrial in origin and not originated from chickens.

Wickramasinghe and his mentor Fred Hoyle have also used their data to argue in favor of cosmic ancestry, and against evolution.

Like I said, big grain of salt. (thx, onno)


Does Every Species Get a Billion Heartbeats Per Lifetime?

There’s an assumption that because of the relationship between metabolic rates, volume, and surface area, animals get an average of one billion heartbeats out of their bodies before they expire. Turns out there’s some truth to it.

One Billion Heartbeats

As animals get bigger, from tiny shrew to huge blue whale, pulse rates slow down and life spans stretch out longer, conspiring so that the number of heartbeats during an average stay on Earth tends to be roughly the same, around a billion.

Mysteriously, these and a large variety of other phenomena change with body size according to a precise mathematical principle called “quarter-power scaling”.

It might seem that because a cat is a hundred times more massive than a mouse, its metabolic rate, the intensity with which it burns energy, would be a hundred times greater. After all, the cat has a hundred times more cells to feed.

But if this were so, the animal would quickly be consumed by a fit of spontaneous feline combustion, or at least a very bad fever. The reason: the surface area a creature uses to dissipate the heat of the metabolic fires does not grow as fast as its body mass.

To see this, consider a mouse as an approximation of a small sphere. As the sphere grows larger, to cat size, the surface area increases along two dimensions but the volume increases along three dimensions. The size of the biological radiator cannot possibly keep up with the size of the metabolic engine.

Humans and chickens are both outliers in this respect…they both live more than twice as long as their heart rates would indicate. Small dogs live about half as long.


Immortality lessons from the humble jellyfish

Looking to live forever? You might want to take a close look at the immortal jellyfish. This death-defying creature ages, but researchers studying the jellyfish found that, instead of dying, it started “to age in reverse, growing younger and younger until it reached its earliest stage of development, at which point it began its life cycle anew.” (If beginning the life cycle anew means another trip through junior high, count me out.) From NYT Magazine: Can a Jellyfish Unlock the Secret of Immortality?


Some birds have a heads-up display compass

Birds can detect the magnetic field of the Earth, which gives them an incredible sense of direction. Curiously, this sense of direction doesn’t work in darkness. This led scientists to discover that some birds can actually see the directions overlaid on their normal vision, like a heads-up display.

According to the new model, when a photon of light from the Sun is absorbed by a special molecule in the bird’s eye, it can cause an electron to be kicked from its normal state into an alternative location a few nanometres away. Until the electron eventually relaxes back, it creates an ‘electric dipole field’ which can augment the bird’s vision - for example altering colours or brightness.

Crucially, the alignment of the molecule compared to the Earth’s magnetic field controls the time it takes for the electron to relax back, and so controls the strength of the effect on the bird’s vision.

There are many such molecules spread throughout the eye, with different orientations. So from the patterns on top of its vision, and the change of these patterns as it moves its head, the bird learns about the direction of Earth’s magnetic field.

(via @daveg)


The human body’s microbial ecosystem

In this transcript of a talk given to the attendees of the Joint Summits on Translational Science, Carl Zimmer highlights an important aspect of understanding the human body and how to treat its many maladies: the ecosystem of microbes.

The microbes in your body at this moment outnumber your cells by ten to one. And they come in a huge diversity of species β€” somewhere in the thousands, although no one has a precise count yet. By some estimates there are twenty million microbial genes in your body: about a thousand times more than the 20,000 protein-coding genes in the human genome. So the Human Genome Project was, at best, a nice start. If we really want to understand all the genes in the human body, we have a long way to go.

Now you could say “Who cares? They’re just wee animalcules.” Those wee animacules are worth caring about for many reasons. One of the most practical of those reasons is that they have a huge impact on our “own” health. Our collection of microbes-the microbiome-is like an extra organ of the human body. And while an organ like the heart has only one function, the microbiome has many.

When food comes into the gut, for example, microbes break some of them down using enzymes we lack. Sometimes the microbes and our own cells have an intimate volley, in which bacteria break down a molecule part way, our cells break it down some more, the bacteria break it down even more, and then finally we get something to eat.

Another thing that the microbiome does is manage the immune system. Certain species of resident bacteria, like Bacteroides fragilis, produce proteins that tamp down inflammation. When scientists rear mice that don’t have any germs at all, they have a very difficult time developing a normal immune system. The microbiome has to tutor the immune system in how to do its job properly. It also acts like an immune system of its own, fighting off invading microbes, and helping to heal wounds.

While the microbiome may be an important organ, it’s a peculiar one. It’s not one solid hunk of flesh. It’s an ecosystem, made up of thousands of interacting species.


Meet LUCA, our distant Earth-sized ancestor

Here’s an interesting hypothesis: that all current life on Earth originated from a planet-wide super-organism named LUCA.

The latest results suggest LUCA was the result of early life’s fight to survive, attempts at which turned the ocean into a global genetic swap shop for hundreds of millions of years. Cells struggling to survive on their own exchanged useful parts with each other without competition β€” effectively creating a global mega-organism.

It was around 2.9 billion years ago that LUCA split into the three domains of life: the single-celled bacteria and archaea, and the more complex eukaryotes that gave rise to animals and plants (see timeline). It’s hard to know what happened before the split. Hardly any fossil evidence remains from this time, and any genes that date that far back are likely to have mutated beyond recognition.

(via @daveg)


Pruney fingers for better gripping

You know how your hands and feet get all wrinkly when they’re immersed in water for a long time? There’s speculation the wrinkles might be an adaptation that allows for better gripping in wet conditions.

Now a paper in the journal Brain, Behavior and Evolution offers more evidence that wet wrinkles serve a purpose. Much like the tread on a tire, they improve traction.

In the study, an evolutionary neurobiologist and his co-authors examined 28 fingers wrinkled by water. They found that they all had the same pattern of unconnected channels diverging away from one another as they got more distant from the fingertips.

The wrinkles allow water to drain away as fingertips are pressed to wet surfaces, creating more contact and a better grip.

(via stellar)


Urban evolution in NYC

Evolutionary biologists are increasingly studying organisms (like mice, fish, and bacteria) in urban areas like New York City to find out how they evolve to urban conditions.

Dr. Munshi-South and his colleagues have been analyzing the DNA of the mice. He’s been surprised to find that the populations of mice in each park are genetically distinct from the mice in others. “The amount of differences you see among populations of mice in the same borough is similar to what you’d see across the whole southeastern United States,” he said.


Leaf recognition software

LeafSnap is a new iPhone app that uses facial recognition techniques to identify trees based on photos of their leaves.

Leafsnap contains beautiful high-resolution images of leaves, flowers, fruit, petiole, seeds, and bark. Leafsnap currently includes the trees of New York City and Washington, D.C., and will soon grow to include the trees of the entire continental United States.

Wow. Garden Design has more info. (thx, claire)


How babby’s fish face is formed

Whoa, watch the video at the top of this article to see how the human face develops in the womb from an age of one-month to ten weeks. It all just comes together right at the end!

If you watch it closely, you will see that the human face is actually formed of three main sections which rotate and come together in an unborn foetus.

The way this happens only really makes sense when you realise that, strange though it may sound, we are actually descended from fish.

The early human embryo looks very similar to the embryo of any other mammal, bird or amphibian β€” all of which have evolved from fish.

Your eyes start out on the sides of your head, but then move to the middle.

The top lip along with the jaw and palate started life as gill-like structures on your neck. Your nostrils and the middle part of your lip come down from the top of your head.

There is no trace of a scar; the plates of tissue and muscle fuse seamlessly. But there is, however, a little remnant of all this activity in the middle of your top lip β€” your philtrum.

(via hypertext)


NASA study of arsenic-based life flawed?

Carl Zimmer in Slate:

Redfield blogged a scathing attack on Saturday. Over the weekend, a few other scientists took to the Internet as well. Was this merely a case of a few isolated cranks? To find out, I reached out to a dozen experts on Monday. Almost unanimously, they think the NASA scientists have failed to make their case. “It would be really cool if such a bug existed,” said San Diego State University’s Forest Rohwer, a microbiologist who looks for new species of bacteria and viruses in coral reefs. But, he added, “none of the arguments are very convincing on their own.” That was about as positive as the critics could get. “This paper should not have been published,” said Shelley Copley of the University of Colorado.

(thx, anil)


Albino redwoods

There may only be a few dozen albino redwoods in the world; they’re difficult to find so no one knows the real number. The albinos lack chlorophyll, making them unable to produce their own food, so they freeload off of a parent tree.

Albino redwood

KQED has a short video segment about the albino redwoods as well.


Discovered: a new form of life

NASA’s astrobiology announcement is that they’ve found a new kind of life that incorporates the normally toxic arsenic into its DNA.

Life like us uses a handful of basic elements in the majority of its biochemistry: carbon, hydrogen, oxygen, and nitrogen for the most part. But phosphorus is also a critical element in two major ways: it’s used as the backbone of the long, spiral-shaped DNA and RNA molecules (think of it as the winding support structure for a spiral staircase and you’ll get the picture), and it’s part of the energy transport mechanism for cells in the form of ATP (adenosine triphosphate). Without it, our cells would literally not be able to reproduce, and we’d be dead anyway if it were gone. There are many other ways phosphorus is used as well, including in cell membranes, bones, and so on. It’s a key element for all forms of life.

[…]

Amazingly, using radioisotope-tagged molecules containing arsenic, they were able to find that the microbes incorporated the arsenic into their very DNA! It’s hard to stress how shocking this is; as I understand it, saying something like that to a microbiologist without evidence would’ve had them slowly backing away from you and looking for weapons or an escape route.

I guessed wrong about what NASA was set to announce today, but the actual announcement is much more interesting than the mere discovery of extraterrestrial life. Aliens are inevitable β€” we’re going to find them sooner or later β€” but a new kind of DNA, that’s not something that happens every day. Exciting! (thx, jon)


Has NASA discovered extraterrestrial life?

Here’s a curious press release from NASA:

NASA will hold a news conference at 2 p.m. EST on Thursday, Dec. 2, to discuss an astrobiology finding that will impact the search for evidence of extraterrestrial life. Astrobiology is the study of the origin, evolution, distribution and future of life in the universe.

I did a little research on the news conference participants and found:

1. Pamela Conrad (a geobiologist) was the primary author of a 2009 paper on geology and life on Mars

2. Felisa Wolfe-Simon (an oceanographer) has written extensively on photosynthesis using arsenic recently (she worked on the team mentioned in this article)

3. Steven Benner (a biologist) is on the “Titan Team” at the Jet Propulsion Laboratory; they’re looking at Titan (Saturn’s largest moon) as an early-Earth-like chemical environment. This is likely related to the Cassini mission.

4. James Elser (an ecologist) is involved with a NASA-funded astrobiology program called Follow the Elements, which emphasizes looking at the chemistry of environments where life evolves (and not just looking at water or carbon or oxygen).

So, if I had to guess at what NASA is going to reveal on Thursday, I’d say that they’ve discovered arsenic on Titan and maybe even detected chemical evidence of bacteria utilizing it for photosynthesis (by following the elements). Or something like that. (thx, sippey)

Update: According to Alexis Madrigal, the answer to the hyperbolic question in the headline is “no”.

I’m sad to quell some of the @kottke-induced excitement about possible extraterrestrial life. I’ve seen the Science paper. It’s not that.


Stem cells to aid the blind

Clinical trials are about to begin where embryonic stem cells will be injected into the eyes of people with Stargardt’s macular degeneration.

Robert Lanza, the company’s chief scientific officer, said that the first patient could receive the stem cell transplants early in the new year and although the trial is designed primarily to assess safety, the first signs of visual improvement may be apparent within weeks. “Talking to the clinicians, we could see something in six weeks, that’s when we think we may see some improvements. It really depends on individual patients but that’s a reasonable time frame when something may start to happen,” Dr Lanza said.


On the merits of premature ejaculation

Evolutionary speaking, premature ejaculation may not be such a bad thing after all.

So given these basic biological facts, and assuming that ejaculation is not so premature that it occurs prior to intromission and sperm cells find themselves awkwardly outside of a woman’s reproductive tract flopping about like fish out of water, what, exactly, is so “premature” about premature ejaculation? In fact, all else being equal, in the ancestral past, wouldn’t there likely have been some reproductive advantages to ejaculating as quickly as possible during intravaginal intercourse-such as, oh, I don’t know, inseminating as many females as possible in as short a time frame as possible? or allowing our ancestors to focus on other adaptive behaviors aside from sex? or perhaps, under surreptitious mating conditions, doing the deed quickly and expeditiously without causing a big scene?

Still, for recreational sex, it blows. (As it were.)


DNA and quantum entanglement

Does quantum entanglement hold DNA together? Some physicists say it’s possible.

Rieper and co ask what happens to these oscillations, or phonons as physicists call them, when the base pairs are stacked in a double helix.

Phonons are quantum objects, meaning they can exist in a superposition of states and become entangled, just like other quantum objects.

To start with, Rieper and co imagine the helix without any effect from outside heat. “Clearly the chain of coupled harmonic oscillators is entangled at zero temperature,” they say. They then go on to show that the entanglement can also exist at room temperature.

That’s possible because phonons have a wavelength which is similar in size to a DNA helix and this allows standing waves to form, a phenomenon known as phonon trapping. When this happens, the phonons cannot easily escape. A similar kind of phonon trapping is known to cause problems in silicon structures of the same size.


DNA copying for everyone

The OpenPCR project is trying to raise $6,000 on Kickstarter to design and build a DNA Xerox machine that costs less than $400, thereby enabling DNA hacking in one’s garage.

In 1983, Kary Mullis first developed PCR, for which he later received a Nobel Prize. But the tool is still expensive, even though the technology is almost 30 years old. If computing grew at the same pace, we would all still be paying $2,000+ for a 1 MHz Apple II computer. Innovation in biotech needs a kick start!

PCR machines currently cost $4-10,000. (via modcult)


Scientists implant transistor in living cell

The man/machine union marches ever closer.

Scientists have embedded a nano-sized transistor inside a cell-like membrane and powered it using the cell’s own fuel. The research could lead to new types of man-machine interactions where embedded devices could relay information about the inner workings of disease-related proteins inside the cell membrane, and eventually lead to new ways to read, and even influence, brain or nerve cells.

When I first saw the headline, I thought that it said “embedded a nano-sized transistor radio“…now that would be something. (via jb)


The long tail of life

There are a ridiculous number of microbes in the Earth’s oceans.

During an 11 month study in 2007, scientists sequenced the genes of more than 180,000 specimens from the Western English Channel. Although this level of sampling “far from exhausted the total diversity present,” they wrote, one in every 25 readings yielded a new genus of bacteria (7,000 genera in all).

That’s genus, not species. Kevin Kelly translates:

This suggests there is a long tail of life in bacteria, with a few species super-abundant, but many many species with very thin populations. At the far end of the tail there may be a billion species with only a few individuals. […] And like other kinds of long tails, the sum of all these small bits total up to exceed the sum of individuals in the most popular species. As the microbiologists involved in the Census of Marine Life like to say, this survey reveals life’s “hidden majority.”


Cloud bacteria brings May showers

Recent evidence suggests that bacteria in clouds may have evolved the ability to make it rain as a way of dispersing themselves around the globe.

The theory-called bioprecipitation-was pioneered by David Sands, a plant pathologist at Montana State University, in the 1980s. But little information existed on how the rainmaking bacteria moved through the atmosphere until Christner and his colleagues began their work in 2005. Sands told National Geographic News that the critters may even employ creative means of transportation: For instance, they could “ride piggyback” on pollen or insects. “We thought [the bacteria] were just plant pathogens [germs], but we found them in mountain lakes, in waterfalls, in Antarctica-they get around,” Sands said.


Killer carnivorous plants

Writing for National Geographic, Carl Zimmer on the fascinating plants that eat animals. Like the Venus flytrap, “an electrical plant”:

When an insect brushes against a hair on the leaf of a Venus flytrap, the bending triggers a tiny electric charge. The charge builds up inside the tissue of the leaf but is not enough to stimulate the snap, which keeps the Venus flytrap from reacting to false alarms like raindrops. A moving insect, however, is likely to brush a second hair, adding enough charge to trigger the leaf to close.

Volkov’s experiments reveal that the charge travels down fluid-filled tunnels in a leaf, which opens up pores in cell membranes. Water surges from the cells on the inside of the leaf to those on the outside, causing the leaf to rapidly flip in shape from convex to concave, like a soft contact lens. As the leaves flip, they snap together, trapping an insect inside.

See also the accompanying photo gallery.


Deforestation changing bird wing shapes

A recent study indicates that the wing shapes of North American birds are changing in response to deforestation.

He found that over half of the species he examined demonstrated changes over time with boreal birds developing more pointed wings and temperate birds developing rounder wings. These results support the hypothesis that habitat isolation is spurring evolutionary changes in birds.

Boreal forests have suffered severe deforestation over the past century, and so Desrochers had predicted that increased distances between habitat patches would select for more pointed wings in birds. Pointed wings are associated with more energy-efficient sustained flight.


Nature’s quantum computers

One of the big bummers about quantum computing is the cold temperatures required (hundreds of degrees below zero). However, a number of researchers believe that certain algae and bacteria perform quantum calculations at room temperature.

The evidence comes from a study of how energy travels across the light-harvesting molecules involved in photosynthesis. The work has culminated this week in the extraordinary announcement that these molecules in a marine alga may exploit quantum processes at room temperature to transfer energy without loss. Physicists had previously ruled out quantum processes, arguing that they could not persist for long enough at such temperatures to achieve anything useful.

(via mr)


Not your father’s evolution

Recent evidence of horizontal gene transfer β€” in which genes are exchanged from other organisms, not from ancestors β€” has some scientists thinking that the dominant form of evolution for most of the Earth’s history was between non-related organisms and not among ancestors.

In the past few years, a host of genome studies have demonstrated that DNA flows readily between the chromosomes of microbes and the external world. Typically around 10 per cent of the genes in many bacterial genomes seem to have been acquired from other organisms in this way, though the proportion can be several times that. So an individual microbe may have access to the genes found in the entire microbial population around it, including those of other microbe species. “It’s natural to wonder if the very concept of an organism in isolation is still valid at this level,” says Goldenfeld.

Read on for their hypothesis about how horizontal evolution drove innovation β€” development of a universal genetic code and genetic innovation-sharing protocols β€” in life forms early on in the Earth’s history. Fascinating.


PageRank useful in determining ecosystem collapse

In addition to its utility in organizing the World Wide Web, researchers say that Google’s PageRank algorithm is useful in studying food webs, “the complex networks of who eats whom in an ecosystem”.

Dr Allesina, of the University of Chicago’s department of ecology and Evolution, told BBC News: “First of all we had to reverse the definition of the algorithm. “In PageRank, a web page is important if important pages point to it. In our approach a species is important if it points to important species.”

The researchers compared the performance of PageRank and found it comparable to that of much more complex computational biology algorithms.


An update on colony collapse disorder

As reported previously, colony collapse disorder seems to have multiple causes. In the NY Times’ Room for Debate blog, several scientists and other bee experts offer their commentary on what we currently know about CCD and what’s being done about it.

Meanwhile, individual beekeeping operations have been damaged, some beyond repair because of this malady. Others have been able to recover. The overall picture is, however, not quite as bleak as the press and the blogosphere might lead you to imagine. Colony numbers in the U.S. show the resiliency of American beekeepers.