-
Παρόμοιο φαινόμενο έχει παρατηρηθεί και σε σαύρες, όπως περιγράφεται και εδώ
Πολύ ενδιαφέρον αυτό το άρθρο με τους σπίνους!
-
Evolution in Action: Lizard Moving From Eggs to Live Birth
A yellow-bellied three-toed skink carrying embryos, visible as light orbs inside its body.PHOTOGRAPH COURTESY REBECCA A. PYLES
Brian Handwerk
for National Geographic News
PUBLISHED SEPTEMBER 1, 2010Evolution has been caught in the act, according to scientists who are decoding how a species of Australian lizard is abandoning egg-laying in favor of live birth.
Along the warm coastal lowlands of New South Wales (map), the yellow-bellied three-toed skink lays eggs to reproduce. But individuals of the same species living in the state's higher, colder mountains are almost all giving birth to live young.
Only two other modern reptiles—another skink species and a European lizard—use both types of reproduction.
Evolutionary records shows that nearly a hundred reptile lineages have independently made the transition from egg-laying to live birth in the past, and today about 20 percent of all living snakes and lizards give birth to live young only.
But modern reptiles that have live young provide only a single snapshot on a long evolutionary time line, said study co-author James Stewart, a biologist at East Tennessee State University. The dual behavior of the yellow-bellied three-toed skink therefore offers scientists a rare opportunity.
'By studying differences among populations that are in different stages of this process, you can begin to put together what looks like the transition from one [birth style] to the other.'
Eggs-to-Baby Switch Creates Nutrient Problem
One of the mysteries of how reptiles switch from eggs to live babies is how the young get their nourishment before birth.
In mammals a highly specialized placenta connects the fetus to the uterus wall, allowing the baby to take up oxygen and nutrients from the mother's blood and pass back waste.
In egg-laying species, the embryo gets nourishment from the yolk, but calcium absorbed from the porous shell is also an important nutrient source.
Some fish and reptiles, meanwhile, use a mix of both birthing styles. The mother forms eggs, but then retains them inside her body until the very last stages of embryonic development.
The shells of these eggs thin dramatically so that the embryos can breathe, until live babies are born covered with only thin membranes—all that remains of the shells.
This adaptation presents a potential nourishment problem: A thinner shell has less calcium, which could cause deficiencies for the young reptiles.
Stewart and colleagues, who have studied skinks for years, decided to look for clues to the nutrient problem in the structure and chemistry of the yellow-bellied three-toed skink's uterus.
'Now we can see that the uterus secretes calcium that becomes incorporated into the embryo—it's basically the early stages of the evolution of a placenta in reptiles,' Stewart explained.
Evolutionary Transition Surprisingly Simple
Both birthing styles come with evolutionary tradeoffs: Eggs are more vulnerable to external threats, such as extreme weather and predators, but internal fetuses can be more taxing for the mother.
For the skinks, moms in balmier climates may opt to conserve their own bodies' resources by depositing eggs on the ground for the final week or so of development. Moms in harsh mountain climates, by contrast, might find that it's more efficient to protect their young by keeping them longer inside their bodies.
In general, the results suggest the move from egg-laying to live birth in reptiles is fairly common—at least in historic terms—because it's relatively easy to make the switch, Stewart said.
'We tend to think of this as a very complex transition,' he said, 'but it's looking like it might be much simpler in some cases than we thought.'
The skink-evolution research was published online August 16 by the Journal of Morphology.
Πηγή: http://news.nationalgeographic.com/news ... irth-eggs/
-
Why you should stop believing in evolution
You don't believe in it — you either understand it or you don'tBy Keith Blanchard | August 4, 2014
When people joyously discover on Ancestry.com that they're related to, say, a medieval archduke or a notorious Victorian criminal, evolutionary biologists may be permitted to snicker. Because in actuality, we are all related: Humans all share at least one common ancestor if you go far enough back. You are related to every king and criminal who ever lived, to Gandhi and Paris Hilton and Carrot Top. You are even related to me.
But buckle up — that's only the beginning.
Humanity, after all, is but one ugly branch on the big tree of life. Go back far enough, and you'll find an ancestor common to you and to every creature on Earth. You are related to your cat — which may help explain why you get that stare all the time. You are related to a Tyrannosaurus Rex, and to the mosquito you just murdered, and to your houseplants. At any given meal, you may eat all or part of a dozen extremely distant relatives.
It's remarkable how poorly understood evolution is today — how easily 'debated' it is — given that its rules have been in place at least since life on Earth began, and that the truth of it is easily demonstrated. In fact, the basic theory has been in a state of continuous reconfirmation since Darwin proposed it in 1859, with geology, biology, anthropology, carbon dating, Pangaea, and every dinosaur bone ever found providing a nonstop barrage of additional proof points.
Here are the rules, in a nutshell:
• Genes, stored in every cell, are the body's blueprints; they code for traits like eye color, disease susceptibility, and a bazillion other things that make you you.
• Reproduction involves copying and recombining these blueprints, which is complicated, and errors happen.
• Errors are passed along in the code to future generations, the way a smudge on a photocopy will exist on all subsequent copies.
• This modified code can (but doesn't always) produce new traits in successive generations: an extra finger, sickle-celled blood, increased tolerance for Miley Cyrus shenanigans.
• When these new traits are advantageous (longer legs in gazelles), organisms survive and replicate at a higher rate than average, and when disadvantageous (brittle skulls in woodpeckers), they survive and replicate at a lower rate.
That's a little oversimplified, but the general idea. As advantageous traits become the norm within a population and disadvantageous traits are weeded out, each type of creature gradually morphs to better fit its environment.
The very notion of 'species' is even a little misleading — a discrete-sounding artifice created for the convenience of people who live about a hundred years. If you had eyes to see the big picture, and could watch life change on a geologic time frame, you'd see constant gradual change, as generations adapt to circumstance.
It's that incredibly slow pace that makes it hard for people to grasp intuitively. When you only live long enough to see three or four generations — a few ticks of evolution's clock — any tiny generational changes, like humanity getting marginally blonder or taller, are dwarfed by differences in the members among any one generation. Pile on enough eons, and tiny pidgin horses gradually become rideable by gradually less hairy apes. But it's impossible to see for yourself.
(iStock)That's evolution left to proceed at its own lazy, trial-and-error pace. But it turns out you can make the gears turn a lot faster — in fact, we do it all the time. Have you ever seen strawberries in the wild? They're little tiny things, easily missed if you are not a bird or a bee. We bred them to be big and fat, specifically by only allowing the seeds from the biggest, fattest ones in each generation to reproduce. We similarly manipulate almost every other 'natural' food we eat today: Take a stroll through any modern produce section and you can see the fruits, literally and figuratively, of evolution turbocharged by human intervention.
Dogs are another example: We invented the dog, starting with wolves and quickening the natural but poky process of evolution by specifically selecting breeding pairs with desirable traits, gradually accentuating particular traits in successive populations. Poodles, Rottweilers, Great Danes, Hollywood red-carpet purse dogs — all this fabulous kinetic art was created, and continues to be created, by humans manually hijacking the mechanism of evolution.
Listen, nobody wants to be related to monkeys. (Scientist 1, after the Scopes trial: 'Well, that was a catastrophe.' Scientist 2: 'Yeah? Wait until they find out they're also related to friggin' carrots.') But 'that's just too crazy to believe' cannot be a defense against science. Why do you have sharp canine teeth? An appendix? Hair under your arms? If your body was designed for its current usage, there's a lot of inefficiency there. If it seems, rather, to be in the process of becoming less…bestial, well, that's because it is.
So if someone asks, 'Do you believe in evolution,' they are framing it wrong. That's like asking, 'Do you believe in blue?'
Evolution is nothing more than a fairly simple way of understanding what is unquestionably happening. You don't believe in it — you either understand it or you don't. But pretending evolution is a matter of faith can be a clever way to hijack the conversation, and pit it in a false duality against religion. And that's how we end up with people decrying evolution, even as they eat their strawberries and pet their dogs, because they've been led to believe faith can only be held in one or the other.
But there's no reason for people of faith to reject the mountains of data and the evidence of their own senses. Reconciling is easy: Believe, if you want to, that God set up the rules of evolution among His wonders, along with the laws of physics, and probability, and everything else we can see and measure for ourselves. But don't deny evolution itself, or gravity, or the roundness of Earth. That's just covering your eyes and ears. And only monkeys would do that.
http://theweek.com/article/index/265653 ... -evolution
-
Πάρα μα πάρα πολλά +
-
Περί εξέλιξης των ειδών...[Διάσπαση]