The Prometheus League
Breaking News and Updates
- Abolition Of Work
- Ai
- Alt-right
- Alternative Medicine
- Antifa
- Artificial General Intelligence
- Artificial Intelligence
- Artificial Super Intelligence
- Ascension
- Astronomy
- Atheism
- Atheist
- Atlas Shrugged
- Automation
- Ayn Rand
- Bahamas
- Bankruptcy
- Basic Income Guarantee
- Big Tech
- Bitcoin
- Black Lives Matter
- Blackjack
- Boca Chica Texas
- Brexit
- Caribbean
- Casino
- Casino Affiliate
- Cbd Oil
- Censorship
- Cf
- Chess Engines
- Childfree
- Cloning
- Cloud Computing
- Conscious Evolution
- Corona Virus
- Cosmic Heaven
- Covid-19
- Cryonics
- Cryptocurrency
- Cyberpunk
- Darwinism
- Democrat
- Designer Babies
- DNA
- Donald Trump
- Eczema
- Elon Musk
- Entheogens
- Ethical Egoism
- Eugenic Concepts
- Eugenics
- Euthanasia
- Evolution
- Extropian
- Extropianism
- Extropy
- Fake News
- Federalism
- Federalist
- Fifth Amendment
- Fifth Amendment
- Financial Independence
- First Amendment
- Fiscal Freedom
- Food Supplements
- Fourth Amendment
- Fourth Amendment
- Free Speech
- Freedom
- Freedom of Speech
- Futurism
- Futurist
- Gambling
- Gene Medicine
- Genetic Engineering
- Genome
- Germ Warfare
- Golden Rule
- Government Oppression
- Hedonism
- High Seas
- History
- Hubble Telescope
- Human Genetic Engineering
- Human Genetics
- Human Immortality
- Human Longevity
- Illuminati
- Immortality
- Immortality Medicine
- Intentional Communities
- Jacinda Ardern
- Jitsi
- Jordan Peterson
- Las Vegas
- Liberal
- Libertarian
- Libertarianism
- Liberty
- Life Extension
- Macau
- Marie Byrd Land
- Mars
- Mars Colonization
- Mars Colony
- Memetics
- Micronations
- Mind Uploading
- Minerva Reefs
- Modern Satanism
- Moon Colonization
- Nanotech
- National Vanguard
- NATO
- Neo-eugenics
- Neurohacking
- Neurotechnology
- New Utopia
- New Zealand
- Nihilism
- Nootropics
- NSA
- Oceania
- Offshore
- Olympics
- Online Casino
- Online Gambling
- Pantheism
- Personal Empowerment
- Poker
- Political Correctness
- Politically Incorrect
- Polygamy
- Populism
- Post Human
- Post Humanism
- Posthuman
- Posthumanism
- Private Islands
- Progress
- Proud Boys
- Psoriasis
- Psychedelics
- Putin
- Quantum Computing
- Quantum Physics
- Rationalism
- Republican
- Resource Based Economy
- Robotics
- Rockall
- Ron Paul
- Roulette
- Russia
- Sealand
- Seasteading
- Second Amendment
- Second Amendment
- Seychelles
- Singularitarianism
- Singularity
- Socio-economic Collapse
- Space Exploration
- Space Station
- Space Travel
- Spacex
- Sports Betting
- Sportsbook
- Superintelligence
- Survivalism
- Talmud
- Technology
- Teilhard De Charden
- Terraforming Mars
- The Singularity
- Tms
- Tor Browser
- Trance
- Transhuman
- Transhuman News
- Transhumanism
- Transhumanist
- Transtopian
- Transtopianism
- Ukraine
- Uncategorized
- Vaping
- Victimless Crimes
- Virtual Reality
- Wage Slavery
- War On Drugs
- Waveland
- Ww3
- Yahoo
- Zeitgeist Movement
-
Prometheism
-
Forbidden Fruit
-
The Evolutionary Perspective
Monthly Archives: February 2020
Middle Township Army recruits receive oath of office from space – Press of Atlantic City
Posted: February 27, 2020 at 1:19 am
MIDDLE TOWNSHIP Two Middle Township High School students and one of their coaches made history Wednesday when they participated in the first oath of military enlistment from space.
Seniors Dylan Hoffman and Anthony Anderson, as well as coach and substitute teacher Donald Justin Rhinesmith, recited the oath from the high school library as spoken by U.S. Army Col. Andrew Morgan, a NASA astronaut aboard the International Space Station.
Its a one-time opportunity, but it will also be in conjunction with the Space Force as the sixth branch of the U.S. military, said Army Staff Sgt. Derek D. Olson, a recruiter in Atlantic and Cape May counties.
MIDDLE TOWNSHIP Four Cumberland County residents were arrested Sunday night after police s
Olson said there are three Army astronauts currently, including Morgan.
The enlistment ceremony was broadcast via Facebook Live from Space Center Houston to more than 1,000 future service members from 150 locations throughout the country.
Olson said that each year, his office enlists about 60 new recruits for the Army.
The Middle Township High School Navy National Defense Cadet Corps joined the recruits for the ceremony Wednesday.
Hoffman, 17, of Cape May Court House, said its always been his dream to enlist in the Army.
My grandfather was in the Army. When I was a kid, he would pull out the uniforms and my grandmother said my eyes would light up, he said.
He said he wants to be in the infantry.
A man from the Villas section of Lower Township was charged after authorities last month fou
Anderson, 18, of Rio Grande, said he decided to enlist because he likes working with his hands, particularly auto mechanics. He said he became interested in the Army when the recruiters visited the school his sophomore year.
Its a pretty amazing experience, Anderson said of the ceremony.
Hoffman said he was honored to be able to participate.
Rhinesmith, 27, of Cape May Court House, a Middle Township High School graduate, hopes to become an officer.
Morgan told the recruits he was only able to become an astronaut because of the opportunities he had in the Army.
All things that are worth doing are hard, said Morgan. Im so proud of you and your decision to serve.
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Mainland Regional High School plays Middle Township in the first round of the CAL girls basketball tournament, in Linwood, Monday, Feb. 24, 2020. (VERNON OGRODNEK / For The Press)
Follow this link:
Middle Township Army recruits receive oath of office from space - Press of Atlantic City
Posted in Space Station
Comments Off on Middle Township Army recruits receive oath of office from space – Press of Atlantic City
The Pentagon Is Working on a Nuclear Thermal Rocket – Popular Mechanics
Posted: at 1:19 am
The Pentagon is working on a nuclear thermal propulsion engine with the goal to be able to drive satellites around in space, The Daily Beast reports. This seems to be a multi-motivated effort to thwart other countries space progress, better mine resources from the moon, and also serve as a weapon. Like a well-rounded athlete or entertainer, the nuclear thermal propulsion system aspires to be a triple threatliterally.
If this sounds somewhat sinister, youre not wrong, although its not any more or less villainous than any other defense thing. But that name...
DARPAs budget request for 2021, which the agency released in early February, asks for $21 million for the Demonstration Rocket for Agile Cislunar Operations program, or DRACO, The Daily Beast says. Cislunar refers to the area between Earth and the moon. Draco has strong malevolent Malfoy energy, but also just means dragon in Latin.
The technology involves a small nuclear reactor mounted on a rocket, where the reactor produces thrust by pushing hot or burning material out of a rear opening. Current satellites have very small thrusters that serve almost exclusively to adjust altitude, and these are often electric, because satellites can gather solar energy for much of the year. Even so, the bursts are typically budgeted rigidly because of the opportunity cost of spending fuel at all.
A highly mobile and powerful satellite thrust system is something new, at least if it gets to the execution phase. Being able to navigate in orbit has been a moonshot goal for all the global powers for a long time; so many ideas exist at many levels of development. There are inherent limitations to vehicles that are meant to stay in orbit and interact with Earths surface. And although the moon obviously orbits Earth and stays in a predictable patternour original satellite!that orbit is hundreds of thousands of miles further away than most of the satellites in orbit.
NASAs IBEX satellite is exceptionally high and near the moon at about 200,000 miles. Most of Earths communications satellites are in an orbit about 22,000 miles up, which is called geostationary orbit because of how these satellites appear to stay with the Earth as it spins. The area between 22,000 and about 239,000 miles is pretty empty, and this is where the U.S. and Chinese militaries and space services imagine their nuclear-thrust cislunar vehicles.
The Daily Beast says the vision for these nuclear reactors includes being assembled, in the Johnny Cash tradition, one piece at a time. This spreads the heavy payload over many rocket launches, but requires the reactor to be put together while in space. The human-occupied International Space Station orbits at around just 250 miles up, and assembly of a nuclear satellite engine would take place far, far above that, so wed need some kind of autonomous or remote assembly.
Today, NASA and the military believe this technology is a good complement to our plans to return to the moon by 2024, for example, and the increase in global government and civilian rocket launches. Its not hard to imagine a future where companies have mines on the moon that are regulated by some kind of cislunar police force. Of course, just because its easy to imagine, that doesnt mean its a good or feasible idea.
Read the original:
The Pentagon Is Working on a Nuclear Thermal Rocket - Popular Mechanics
Posted in Space Station
Comments Off on The Pentagon Is Working on a Nuclear Thermal Rocket – Popular Mechanics
Fort Leonard Wood to live stream International Space Station Oath of Enlistment Ceremony – The Rolla Daily News
Posted: at 1:19 am
Fort Leonard Wood
WednesdayFeb26,2020at11:02AMFeb26,2020at11:06AM
St. Robert Recruiting Station, in partnership with NASA and Space Center Houston, will host the first ever, nationwide live oath of enlistment ceremony from space.
FORT LEONARD WOOD Six future Soldiers will raise their hands in an oath of enlistment ceremony with U.S. Army Col. and NASA astronaut Andrew Morgan at Waynesville High School at 11:40 a.m.
A live stream of this ceremony can be found on the Fort Leonard Wood Facebook page atwww.facebook.com/fortleonardwoodmissouri/and on the U.S. Army Recruiting Command (USAREC) Facebook page atwww.facebook.com/USAREC/.
St. Robert Recruiting Station, in partnership with NASA and Space Center Houston, will host the first ever, nationwide live oath of enlistment ceremony from space. More than 850 Future Soldiers will participate at more than 130 locations across the country.
At the completion of the ceremony, Morgan will conduct a question-and-answer session with the new enlistees at Space Center Houston and participating venues from across the country.
Only 29 percent of youth meet the minimum qualifications to serve as a Soldier.
Those who meet the requirements and are selected to serve receive top-notch technical training and education in more than 150 career fields, with almost a third of those in STEM-related fields.
Excerpt from:
Fort Leonard Wood to live stream International Space Station Oath of Enlistment Ceremony - The Rolla Daily News
Posted in Space Station
Comments Off on Fort Leonard Wood to live stream International Space Station Oath of Enlistment Ceremony – The Rolla Daily News
Space cookies and the future of pizza pockets beyond Earth – Boing Boing
Posted: at 1:19 am
Last month, the first cookies baked in space returned to Earth. This test of a new oven designed for microgravity aboard the International Space Station was not only a delightful experiment but also an important one. After all, this was the first time astronauts cooked raw ingredients in space. And yes, the ISS did smell of fresh-baked cookies. From Space.com's interview with NASA astronaut Mike Massimino who consulted on the experiment back on Earth:
Further investigation and analysis of the experiment's results will also continue to answer questions, such as why the cookies took much longer to bake in space and why they weren't "poofy...."
"This is a big step in that direction for the future of exploration where we're gonna be off the planet for longer periods of time," Massimino said. He continued, adding that within the very near future we may be starting to build settlements on off-Earth location like the moon, and we will need to use specialized tech to ensure that the humans living off-Earth have access to good, nutritious (and delicious) food.
As far as what might be next for baking or cooking in space, Massimino had a couple of suggestions.
So what does Massimino want to see next? "The next thing would definitely be a pizza of some sort," he said. "Bagel bites or hot pockets of some sort." He added that it would also be nice for astronauts to have something they could "bite into something big like a big cheeseburger or a big sandwich."
image: NASA
With the illustrious name Temporarily Captured Object 2020 CD3, Earths new moon might not be entertaining a manned landing at any time in the future. Especially since its only a few feet wide. But the tiny sattelite, spotted February 15 with the Catalina Sky Survey in Arizona, is something to celebrate all the same. Our []
SpaceX and Space Adventures have partnered to offer space tourists a trip to orbit on the SpaceX Crew Dragon space capsule. They expect the first flight to launch in late 2021 or early 2022. Around $50 million will get you a seat. From Spaceflight Now: The mission would not dock with the space station, but []
Thirty years ago today, the Voyager 1 spaceprobe had completed its ncounters with the outer planets and was careening out of our solar system. The time came to shut off the probes cameras to preserve power and memory for the other onboard scientific instruments. But before engineers flipped the switch, one last photo opportunity was []
Whether youre managing a political campaign or building a client base, there comes a time when you stop seeing people and start seeing numbers. This doesnt happen suddenly. You shake hands, make calls, and build relationships. And then those relationships disappear into a database of donors or customers as your organization grows. People get brought []
Learning to ride a bike is one of those quintessential childhood experiences thats as rewarding as it is scary. Prep your precious babe for success by starting them early with the worlds lightest balance bike, the Brilrider FLIGHT. For the uninitiated, balance bikes are no-pedal bicycles that propel forward by pushing off the ground with []
With so many advancements in modern society, youd think wed have moved beyond the butane lighter by now. A pressurized, flammable gas, butane fumes can irritate your eyes and skin, can elevate your heart rate, and even lead to cardiac arrest. And we did mention that whole highly pressurized and flammable part, right? While certainly []
Excerpt from:
Space cookies and the future of pizza pockets beyond Earth - Boing Boing
Posted in Space Station
Comments Off on Space cookies and the future of pizza pockets beyond Earth – Boing Boing
Recovering A Strong American Conception Of Property Rights – The Federalist
Posted: at 1:18 am
Within our constitutional framework, property rights have been relegated to second-class citizenship.
Take the Supreme Courts double-standard on the Fifth Amendments prohibition against the government taking private property unless its for public use. For alleged infringements of other guarantees in the Bill of Rights, the Court strictly scrutinizes government action. But with the Fifth Amendments property protections, the Court allows legislatures to interpret their own constitutional boundaries. If only property rights are at stake, then the fox may guard the henhouse.
Or consider the Courts amorphous review for substantive due process, a values-based inquiry into the constitutional legitimacy of state and federal regulatory laws. On this score, the Court candidly concedes that property rights and contractual freedoms enjoy less protection than other, non-economic liberties.
In his new book Property and the Pursuit of Happiness: Locke, the Declaration of Independence, Madison, and the Challenge of the Administrative State, Edward Erler shows how constitutional property rights climbed through the looking glass and came out topsy-turvy. From Americas founding era to the present day, property rights flipped from cachet to low-caste, and whats supposed to be up, well, is down.
Erler is a professor of political philosophy, so its unsurprising this books foremost contribution is its discussion of the vital role property rights played in the Framers constitutional vision. Tracing an arc of political thought from Aristotle through Locke on to the Declaration of Independence, Erler argues that the Founding Fathers put an inherently American gloss on pre-existing conceptions of property one that merged natural rights and moral obligation into a synthesis they called the pursuit of happiness.
For the Founders, the right to property was the comprehensive right that included all other rights. In this spirit, the Supreme Court in 1795 averred that the right of acquiring and possessing property, and having it protected, is one of the natural, inherent and unalienable rights of man.
Erler explains the decline of property rights from these sanctified heights. As the economy advanced and governments grew, vested property interests came increasingly into conflict with public policy, and it fell to the courts to demarcate the boundaries between public and private spheres.
For much of our nations history, as courts wrestled with these controversies, they hewed to an understanding of property rights closer the Framers than what we see today. The practical result was that property rights enjoyed considerable constitutional protection from overbearing government.
But the scales of justice shifted early in the twentieth century, when the Progressive forces of history swept first into legislatures and then into the courts. Progressives rejected the Founders conception of property rights because it impeded the science of economic planning. As Progressive influence waxed, property rights waned.
Although Property and the Pursuit of Happiness overlaps in subject and tone with Richard Epsteins excellent 2008 book, Supreme Neglect: How to Revive Constitutional Protection for Private Property, the two books are complementary but not the same. Discussion of the Founding Fathers is largely absent from the latterarguably the only flaw in Epsteins seminal workand this topic is Erlers strongest contribution.
This is not to say that Property and the Pursuit of Happiness is flawless. In the introduction, Erler warns that he test[s] the patience of the reader on some occasions, and hes not lying. The book is needlessly difficult. Relatedly, he peppers his prose with awkward sentence introductions (e.g., In a statement that is not entirely hyperbolic . . .). Further, the books subtitle, which mentions the Challenge of the Administrative State, engages in a bit of false advertising, as Erler gives the topic only a cursory examination.
Notwithstanding these drawbacks, Property and the Pursuit of Happiness is an important contribution to a growing body of scholarship pushing for a restoration of property rights to their original place among our individual freedomsparticularly with respect to the Fifth Amendments Takings Clause.
The good news is that these ideas are taking root. To wit, the Trump administration is reshaping the federal judiciary with a generation of judges affected by Richard Epsteins work. On the other side of the bar, dogged public interest lawyersmost notably those at the Pacific Legal Foundationhave advanced property rights in courts across the country. After decades, all this effort is paying off.
Consider the blowback to the Supreme Courts infamous holding 15 years ago in Kelo v. City of New London, which allows government to condemn peoples homes and give their land to a corporation in the name of economic development. As Ilya Somin explains in his book The Grasping Hand, many state courts reacted to Kelo by tightening restrictions on the use of eminent domain.
Last Summer, the Court handed down a watershed decision in Knick v. Township of Scott, which basically puts property rights (and Fifth Amendment takings claims, specifically) on the same procedural footing as other guarantees enumerated in the Bill of Rights. The Courts newest members, Justices Neil Gorsuch and Brett Kavanaugh, joined Chief Justice John Robertss Knick opinion. The holding is a bold step towards ending the inequality of our constitutional rights.
None of these welcome developments would have happened absent the toils of scholars and practitioners who laid the foundations for a resurgence of property rights. With Property and the Pursuit of Happiness, Erler adds a valuable voice to this worthy cause.
William Yeatman is a research fellow at the Cato Institute in Washington, D.C.
Read more from the original source:
Recovering A Strong American Conception Of Property Rights - The Federalist
Posted in Fifth Amendment
Comments Off on Recovering A Strong American Conception Of Property Rights – The Federalist
Genome | Definition of Genome by Merriam-Webster
Posted: at 1:17 am
To save this word, you'll need to log in.
These example sentences are selected automatically from various online news sources to reflect current usage of the word 'genome.' Views expressed in the examples do not represent the opinion of Merriam-Webster or its editors. Send us feedback.
1926, in the meaning defined above
German Genom, from Gen gene + -om (as in Chromosom chromosome)
Cite this Entry
Genome. Merriam-Webster.com Dictionary, Merriam-Webster, https://www.merriam-webster.com/dictionary/genome. Accessed 27 Feb. 2020.
More Definitions for genome
: one haploid set of chromosomes with the genes they contain broadly : the genetic material of an organism The idea behind sequencing an organism's genomedecoding, letter by letter, the message contained in every last one of its genesis that it would tell us a lot about how the organism works. Lori Oliwenstein, Discover, January 1996
Comments on genome
What made you want to look up genome? Please tell us where you read or heard it (including the quote, if possible).
Originally posted here:
Genome | Definition of Genome by Merriam-Webster
Posted in Genome
Comments Off on Genome | Definition of Genome by Merriam-Webster
Genomic evidence for two phylogenetic species and long-term population bottlenecks in red pandas – Science Advances
Posted: at 1:17 am
Abstract
The red panda (Ailurus fulgens), an endangered Himalaya-endemic mammal, has been classified as two subspecies or even two species the Himalayan red panda (A. fulgens) and the Chinese red panda (Ailurus styani) based on differences in morphology and biogeography. However, this classification has remained controversial largely due to lack of genetic evidence, directly impairing scientific conservation management. Data from 65 whole genomes, 49 Y-chromosomes, and 49 mitochondrial genomes provide the first comprehensive genetic evidence for species divergence in red pandas, demonstrating substantial inter-species genetic divergence for all three markers and correcting species-distribution boundaries. Combined with morphological evidence, these data thus clearly define two phylogenetic species in red pandas. We also demonstrate different demographic trajectories in the two species: A. styani has experienced two population bottlenecks and one large population expansion over time, whereas A. fulgens has experienced three bottlenecks and one very small expansion, resulting in very low genetic diversity, high linkage disequilibrium, and high genetic load.
The delimitation of species, subspecies, and population is fundamental for insights into the biology and evolution of species and effective conservation management. Traditionally, species, subspecies, or population delimitation is based on reproductive isolation, geographic isolation, and/or morphological differences and does not consider the role of gene flow. The misclassification of basal taxa will result in erroneous or misleading conclusions about the species evolutionary history and adaptive mechanisms, and potentially inappropriate conservation management decisions for threatened species (1, 2).
The red panda (Ailurus fulgens), an endangered Himalaya-endemic mammal, was once widely distributed across Eurasia but is now restricted at the southeastern and southern edges of the Qinghai-Tibetan Plateau within an altitude range of 2200 to 4800 m (3). On the basis of differences in morphology (e.g., skull morphology, coat color, and tail ring) and geographic distribution (Fig. 1 and table S1), red pandas are classified into two subspecies, the Himalayan subspecies (A. f. fulgens Cuvier, 1825) and the Chinese subspecies (A. f. styani Thomas, 1902) (4, 5). Morphologically, the Chinese subspecies has much larger zygomatic breadth, the greatest skull length, stronger frontal convexity, more distinct tail rings, and redder face coat color with less white on it (Fig. 1) (5, 6). On the basis of these morphological differences, C. Groves even proposed that the two subspecies should be updated as two distinct species: the Himalayan red panda (A. fulgens) and the Chinese red panda (A. styani) (6). The Nujiang River is considered the geographic boundary between the two species (7). The Himalayan red panda is distributed in Nepal, Bhutan, northern India, northern Myanmar, and Tibet and western Yunnan Province of China, while the Chinese red panda inhabits Yunnan and Sichuan provinces of China. The subspecies or species classification has remained controversial largely due to the lack of genetic evidence, and their distribution boundary may also be inaccurate because of the morphological similarity of red pandas on both sides of the Nujiang River (6, 8, 9). For instance, the skull size and morphology of red pandas from southeastern Tibet were more similar to those of the Chinese red panda than the Himalayan red panda (6). Although previous studies attempted to use mitochondrial DNA or microsatellite markers to explore this problem, the very small sample size from the Himalayan red panda and the limited ability of the molecular markers resulted in failure to resolve the species delimitation (1012). Next-generation sequencing technology not only provides whole-genome data but also enables the identification of Y chromosome sequences in nonmodel animals, which were difficult to obtain previously (13, 14). Thus, it is now feasible to use whole genomes, Y chromosomes, and mitochondrial genomes to comprehensively delimit species, subspecies, and populations. Here, with sufficient sampling of the Himalayan red panda, we performed whole-genome resequencing, Y chromosome single-nucleotide polymorphism (SNP) genotyping, and mitochondrial genome assembly of wild red pandas covering most of the distribution ranges of the two species, aiming to clarify species differentiation, population divergence, demographic history, and the impacts of population bottlenecks on genetic evolutionary potential.
(A and C) The Chinese red panda. (B and D) The Himalayan red panda. (A and B) The face coat color of the Chinese red panda is redder with less white on it than that of the Himalayan red panda. (C and D) The tail rings of the Chinese red panda are more distinct than those of the Himalayan red panda, with the dark rings being more dark red and the pale rings being more whitish. Photo credit: (A) Yunfang Xiu, Straits (Fuzhou) Giant Panda Research and Exchange Center, China; does not require permission. (B) Arjun Thapa, Institute of Zoology, Chinese Academy of Sciences. (C) Yibo Hu, Institute of Zoology, Chinese Academy of Sciences. (D) Chiranjibi Prasad Pokheral, Central Zoo, Jawalkhel, Lalitpur, Nepal; does not require permission.
We performed whole-genome resequencing for 65 wild red pandas, with an average of 98.7% genome coverage and 13.9-fold sequencing depth for each individual based on the red panda reference genome (belonging to the Chinese red panda) of 2.34 Gb (15). Using the SNP-calling strategy of the Genome Analysis Toolkit (GATK), we identified a total of 4,932,036 SNPs for further analysis (table S4). On the basis of the whole-genome SNPs, the phylogenetic tree, principal components analysis (PCA), and ADMIXTURE results revealed substantial genetic divergence between the two species, providing the first genomic evidence of species differentiation (Fig. 2, B to D). The middle Himalaya population (MH) belonging to the Himalayan red panda was first divergent from the populations of the Chinese red panda (Fig. 2, B and D). Furthermore, four distinct genetic populations were identified: MH (n = 18), eastern Himalaya-Gaoligong (EH-GLG, n = 3 and 13, respectively), Xiaoxiangling-Liangshan (XXL-LS, n = 12 and 8, respectively), and Qionglai (QL, n = 10) (Fig. 2, B to D; fig. S1; and table S5). The individual SLL1 is the only sampled red panda from the Saluli Mountains (SLL), and its genetic assignment implied gene flow between the SLL population and its adjacent XXL and GLG populations (Fig. 2C). Because of the very small sample size, SLL1 was excluded in any population-level analyses. Traditionally, MH, EH, and the GLG individuals at the western side of the Nujiang River were classified as the Himalayan red panda, while the GLG individuals at the eastern side of Nujiang River, XXL, LS, and QL belonged to the Chinese red panda (7). Our results did not support the Nujiang River as the species distribution boundary because the EH and part of the GLG population at the western side of the Nujiang River clustered into a genetic population with other GLG individuals at the eastern side (Fig. 2, B to D). This EH-GLG genetic clustering was supported by morphological evidence that the morphology of red panda skulls from southeastern Tibet (namely, the EH population in this study) was more similar to that of the Chinese red panda than the Himalayan red panda (6). In addition, two individuals from Myanmar (GLG5 and GLG6) also clustered within the EH-GLG genetic cluster, suggesting that the Myanmar population belongs to the Chinese red panda. Thus, we infer that the Yalu Zangbu River, the largest geographic barrier to dispersal between the two species, may be the potential boundary for species distribution (Fig. 2A), although additional samples need to be collected from Bhutan and India to verify this inference.
(A) The geographic distribution of wild red panda samples under the background of habitat suitability. Red, QL population; purple, XXL-LS population; blue, SLL population; pink, EH-GLG; dark red, MH. (B) Maximum likelihood phylogenetic tree based on whole-genome SNPs, with the ferret as the outgroup. The values on the tree nodes indicate the bootstrap support of 50%. (C) ADMIXTURE result based on whole-genome SNPs with K = 2 to 7. (D) PCA result based on whole-genome SNPs. (E) Network map based on eight Y chromosome SNP haplotypes. (F) Network map based on 41 mitochondrial genome haplotypes.
Within the Chinese red panda, we further found population genetic differentiation. EH-GLG first diverged with XXL-LS-QL and then QL separated from XXL-LS (Fig. 2, B and C). Notably, we did not detect genetic substructure within EH-GLG spanning the famous Three Parallel Rivers (Nujiang River, Lancangjiang, and Jinshajiang), suggesting that the three large rivers did not hinder the gene flow of red pandas. This result is consistent with data from microsatellite markers (12).
Our Y chromosome SNP and mitochondrial genome results also supported the substantial divergence between the two species (Fig. 2, E and F; figs. S2 and S3; and tables S6 to S8). The haplotype networks and phylogenetic trees of both eight Y chromosome SNP (Y-SNP) haplotypes from 49 male individuals and 41 mitochondrial genome haplotypes from 49 individuals showed that the MH haplotypes (Himalayan red panda) clustered together and separated from the haplotypes of the Chinese red panda, highlighting the notable genetic divergence between the two species. In summary, regardless of the whole-genome SNPs, Y-SNPs, or mitochondrial genomes, notable genetic differentiation was found between the two species. Our comprehensive investigations reveal two evolutionarily significant units in red pandas. Under the phylogenetic species concept (16), it is reasonable to propose two species: the Himalayan red panda (A. fulgens) and the Chinese red panda (A. styani). This phylogenetic species classification was supported by their morphological differences (6).
The Y chromosome SNP and mitochondrial genome results revealed a female-biased gene flow pattern in red pandas (Fig. 2, E and F). Within the Chinese red panda, we observed different phylogeographic patterns between the mitochondrial genome and Y chromosome. The distribution of mitochondrial haplotypes was mixed and was not associated with the geographic sources of the individuals. By contrast, the distribution of Y-SNP haplotypes demonstrated an obvious phylogeographic structure: The haplotypes of EH-GLG were separated from those of XXL-LS-QL, and no shared Y-SNP haplotypes were found. These contrasting phylogeographic patterns reflected a female-mediated historical gene flow, implying female-biased dispersal and male-biased philopatry in red pandas. This dispersal pattern differs from the male-biased dispersal found in most mammals (17) but is similar to that of another bamboo-eating mammal, the giant panda (18, 19).
The pairwise sequentially Markovian coalescent (PSMC) analysis results showed that the demographic history of red panda could be traced back to approximately 3 million years (Ma) ago, and the two red panda species experienced obviously different demographic histories (Fig. 3A). The Chinese red panda from EH-GLG, XXL-LS, and QL experienced similar demographic trajectories: two population bottlenecks and one large population expansion. This species suffered from an obvious population decline approximately 0.8 Ma ago, which coincided with the occurrence of the Naynayxungla Glaciation (0.78 to 0.5 Ma ago). The population decline resulted in the first bottleneck approximately 0.3 Ma ago, mostly likely caused by the Penultimate Glaciation (0.3 to 0.13 Ma ago) (20). After the glaciations, the populations started to expand and reached a climax approximately 50 thousand years (ka) ago. Then, the arrival of the last glaciations again resulted in rapid population decline, and the second bottleneck occurred during the Last Glacial Maximum (~20 ka ago) (20).
(A) PSMC analysis revealed different demographic histories of the two species, with a generation time (g) of 6 years and a mutation rate () of 7.9 109 per site per generation. The time axis is logarithmic transformed. (B) Fastsimcoal2 simulation reconstructed the divergence, admixture, and demographic history of red panda species and populations. The time axis is logarithmic transformed, and the number of migrants per year between two adjacent populations is shown beside each arrow. (C) TreeMix analysis detected significant gene flow from the EH-GLG to XXL-LS populations. s.e., standard error.
The Himalayan red panda from MH underwent a demographic history differing from that of the Chinese red panda: three population bottlenecks and one small expansion (Fig. 3A). The difference began with the first population bottleneck approximately 0.25 Ma ago. In contrast to the subsequent population recovery of the Chinese red panda, the Himalayan red panda continued to decrease and then went through a second bottleneck approximately 90 ka ago. Afterward, the population started to increase very slowly, but soon the population again decreased due to the last glaciations. The PSMC results showed that even at the climax of population growth (~50 ka ago), the effective population size of the Himalayan red panda was only approximately 35% that of the Chinese red panda. In addition, the Bayesian skyline plot (BSP) analyses based on mitochondrial genomes indicated that both species experienced recent population declines most likely caused by the Last Glacial Maximum, supporting the PSMC results (fig. S4). The different demographic trajectories may result from geographic and climate differences. The Chinese red panda was mainly distributed in the Hengduan Mountains rather than the platform or adjacent edges of the Qinghai-Tibetan Plateau and thus might have suffered less impact of the Pleistocene glaciations. The interglacial warm climate and the vast region of the Hengduan Mountains might have facilitated the rapid population expansion of the Chinese red panda (3). By contrast, the Himalayan red panda lived in the adjacent southern edge of the Qinghai-Tibetan Plateau and might have suffered severe impact of the Pleistocene glaciations. Even during the interglacial period, the geographic proximity to glaciers and limited potential habitat might have restricted this species population recovery (21). In Holocene, the climate might have less impact on red panda populations (21), while increasing human activities became the main factor driving recent red panda population declines, which have been detected by microsatellite marker-based Bayesian population simulations (12).
We further uncovered the species/population divergence history using Fastsimcoal2 simulation. On the basis of the comparison of alternative population divergence models, we determined the best-support divergence/demography model (Fig. 3B, fig. S5, and table S9). The divergence between the Himalayan (MH) and Chinese red pandas (EH-GLG, XXL-LS, and QL) occurred 0.22 Ma ago, coincident with the first population bottleneck of the two species caused by the Penultimate Glaciation. Next, EH-GLG and XXL-LS-QL diverged 0.104 Ma ago. The divergence may have resulted from the widely unsuitable habitat located in the Daxueshan and SLL Mountains (21). Last, XXL-LS and QL diverged 26 ka ago, which was most likely caused by the Last Glacial Maximum. After the population divergence, MH, EH-GLG, and QL suffered from population decline, whereas XXL-LS experienced population growth. Asymmetrical gene flow was detected between adjacent divergent populations (Fig. 3B). After the early divergence between the two species, more gene flow occurred from the Chinese red panda to the Himalayan red panda. Regardless of historical or current gene flow, EH-GLG seemed to be the source population of gene flow with more gene flow into other adjacent populations, among the four genetic populations (Fig. 3B). This implies that EH-GLG might be the historical dispersal source of red pandas. TreeMix analysis also detected significant gene flow from EH-GLG to XXL-LS (Fig. 3C and fig. S6), consistent with the Fastsimcoal2 result.
Whole-genome variation analysis revealed that EH-GLG had the highest genetic diversity ( = 6.994 104, w = 5.271 104), whereas the Himalayan red panda (MH) had the lowest genetic diversity ( = 3.523 104, w = 2.428 104) (Fig. 4A and table S10). Y-SNP and mitochondrial genomic variations also showed that the Himalayan red panda (MH) had the lowest genetic variations (Fig. 4A and table S10). Genome-wide linkage disequilibrium (LD) analysis demonstrated that the Himalayan red panda (MH) had higher level of LD and slower LD decay with a reduced R2 correlation coefficient becoming stable at a distance of approximately 100 kb, whereas the populations of the Chinese red panda exhibited rapid LD decay with a reduced R2 becoming stable at a distance of approximately 40 kb (Fig. 4B). The genomic variations and LD patterns imply different demographic histories of the two species and, in particular, reflect the genetic impacts of long-term population bottlenecks in the Himalayan red panda.
(A) Genetic variations (nucleotide diversity) of different species and populations based on whole-genome SNPs, mitochondrial genomes, and Y chromosome SNPs. (B) LD of the four populations. (C) Ratios of homozygous derived deleterious or LoF variants to homozygous derived synonymous variants for different populations. The horizontal bars denote population means. (D) Distribution of ratios (non-MH/MH) and Z(FST) values. Data points located to the left of the left vertical dashed lines and the right of the right vertical dashed lines (corresponding to the 5% left and right tails of the empirical ratio distribution, respectively) and above the horizontal dashed line [the 5% right tail of the empirical Z(FST) distribution] were identified as selected regions for the MH (the Himalayan red panda, green points) and non-MH (the Chinese red panda, blue points) populations.
We further analyzed the relationship between demographic history and genetic loads carried by different red panda populations, as deleterious variations should be removed more efficiently in larger populations (22, 23). We investigated the distributions of four types of variations [loss of function (LoF), deleterious, tolerated, and synonymous mutations] in protein-coding genes. We found that the ratios of homozygous derived deleterious or LoF variants to homozygous derived synonymous variants were higher in the Himalayan red panda (MH) than in the Chinese red panda; by contrast, the ratios of nonhomozygous derived deleterious or LoF variants to nonhomozygous derived synonymous variants were comparable between the two species (Fig. 4C). This genetic load pattern showed that the Himalayan red panda experiencing long-term population bottlenecks carried more homozygous LoF and deleterious mutations and thus suffers a higher risk of continuing population decline.
Considering that the two red panda species live in different geographic ranges and climate environments and experienced long-term genetic divergence, we mainly focused on the identification of genomic signatures of selection and local adaptation between the two species. Using FST and methods, we identified 146 genes with top 5% maximum FST values and top 5% minimum 1/2 values in the Himalayan red panda (MH) (Fig. 4D and table S11). The functional enrichment found that some genes were enriched in the Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways of vascular smooth muscle contraction (ko04270, P = 1.18 108) and melanogenesis (ko04916, P = 2.36 104) and the gene ontology (GO) term of positive regulation of endothelial cell proliferation (GO:0001938, P = 0.0197) (tables S12 and S13). The selection of these genes might be related with the distinct coat color of the Himalayan red panda and the adaptation to hypoxia and microclimate in high-elevation habitat (6).
In the Chinese red panda (EH-GLG, XXL-LS, and QL), we identified 178 genes under selection (Fig. 4D and table S14), which were partly enriched in the nonhomologous end-joining pathway (ko03450, P = 9.89 103) and the GO terms of regulation of response to DNA damage stimulus (GO:2001020, P = 3.35 103), cellular response to x-ray (GO:0071481, P = 3.69 103), double-strand break repair via nonhomologous end joining (GO:0006303, P = 0.0189), endothelial cell differentiation (GO:0045446, P = 0.0187), and regulation of response to oxidative stress (GO:1902882, P = 0.021) (tables S15 to S16). These selected genes were most likely involved in the adaptation to high ultraviolet radiation and hypoxia and microclimate in the Hengduan Mountains where the Chinese red panda mainly lives. Considering the recent divergence (0.22 Ma ago) between the Himalayan and Chinese red pandas, the ancestor of the two species should have adapted to a high-elevation environment before divergence because the latest and most significant uplift of the Qinghai-Tibetan Plateau have occurred 1.1 to 0.6 Ma ago and caused the altitude to increase up to 3000 m (24). Finding their common genetic mechanisms for high-elevation adaptation proved to be difficult based on our comparison of population genome data. The above functional enrichment results more likely reflected the adaptation of both red pandas to the local microclimate and habitat environment. Recent study showed that the two red panda species have separate climatic spaces dominated by precipitation-associated variables in the Himalayan red panda and by temperature-associated variables in the Chinese red panda (21).
Our analyses of whole genomes, Y chromosomes, and mitochondrial genomes revealed substantial genetic differentiation between the Himalayan and Chinese red pandas and provide the most comprehensive genetic evidence of species delimitation. When combined with previously identified morphological differences (6), the classification of two phylogenetic species is well defined. Our genomic evidence rejected the previous viewpoint of the Nujiang River as the species distribution boundary and revealed that the red pandas living in southeastern Tibet and northern Myanmar belong to the Chinese red panda, while the red pandas inhabiting southern Tibet belong to the Himalayan red panda together with the Nepalese individuals. We infer that the Yalu Zangbu River is most likely the geographic boundary for species distribution because this river is the largest geographic barrier between the two species. However, further verification with samples from Bhutan and India is needed. The delimitation of two red panda species has crucial implications for their conservation, and effective species-specific conservation plans could be formulated to protect the declining red panda populations (25). For a long time, the unclear status of species classification and distribution boundary hindered the scientific design of conservation measures. Because of the wrong distribution boundary, the EH-GLG population was split to belong to two species, which could result in inappropriate conservation measures for EH-GLG population and possibly detrimental interbreeding between the two species in captivity. Within the Chinese red panda, our results revealed three genetic populations: EH-GLG, XXL-LS, and QL, suggesting three management units for scientific conservation. In particular, the EH-GLG population spans southeastern Tibet and northwestern Yunnan of China, northern Myanmar, and northeastern India, which needs transboundary international cooperation for effective conservation. The QL population has the lowest genomic diversity and thus needs more attention to the conservation of its genetic evolutionary potential.
Our findings uncover the genetic impacts of long-term population bottlenecks in the Himalayan red panda, thus providing critical insights into the genetic status and evolutionary history of this poorly understood species. The long-term population bottleneck severely impaired its genetic evolutionary potential, resulting in the lowest genetic diversity but higher genetic load. The Himalayan red panda was estimated to have a small population size (26), and thus maintaining and increasing this species population size and genetic diversity are critical for their long-term persistence. In particular, the Himalayan red panda population spans southern Tibet of China, Nepal, India, and Bhutan, which needs urgent transboundary international cooperation to protect this decreasing species.
Our findings reveal that in addition to Pleistocene glaciations and recent human activity, female-biased gene flow has played an important role in shaping the demographic trajectories and genetic structure of red pandas. As a Himalaya-endemic species, our findings will also help understand the phylogeographic patterns of fauna distributed in the Himalaya-Hengduan Mountains biodiversity hotspot.
We collected blood, muscle, and skin samples of 65 wild red pandas from seven main geographic populations for whole-genome resequencing. Of the 65 individuals, 18 individuals were from the middle Himalayan Mountains (MH), 3 from the eastern Himalayan Mountains (EH), 13 from the Gaoligong Mountains (GLG), 1 from the Saluli Mountains (SLL), 12 from the Xiaoxiangling Mountains (XXL), 8 from the Liangshan Mountains (LS), and 10 from the Qionglai Mountains (QL) (Fig. 2A and table S2). For Y chromosome SNP genotyping, we first used red pandaspecific sex determination primers (27) to identify the sexes of the available wild samples. As a result, 49 wild male red pandas were used, including 13 from the MH population, 2 from EH, 10 from GLG, 8 from XXL, 5 from LS, and 11 from QL (table S2). For mitochondrial genome assembly, we successfully assembled 49 complete mitochondrial genomes from the whole-genome resequencing data for 49 of 65 wild red pandas, including 13 from MH, 2 from EH, 9 from GLG, 12 from XXL, 4 from LS, and 9 from QL (table S2).
We extracted genomic DNA from blood, muscle, and skin samples using the QIAGEN DNeasy Blood & Tissue Kit. Then, we constructed genomic libraries of insert size 200 to 500 base pairs and performed genome resequencing of the average 10 for each individual using the Illumina HiSeq 2000 and X Ten sequencing platforms (table S3). To identify population-level SNPs, the Illumina sequencing reads were aligned to the red panda reference genome (15) with Burrows-Wheeler Alignment (BWA) tool v0.7.8 (28), and polymerase chain reaction (PCR) duplicates were removed by SAMtools v0.1.19 (29). The UnifiedGenotyper method in GATK v3.1-1-g07a4bf8 software (30) was used for SNP calling with default parameters across the 65 individuals. To obtain reliable SNP, we performed a filtering step with the following set of parameters: depth 4, MQ 40, FS 60, QD 4, maf 0.05, and miss 0.2.
Previously, we de novo sequenced a wild male red panda genome (15), which enabled us to develop Y chromosome SNPs. Using a genome synteny searching strategy and the female dog genome (boxer breed) and the dog male-specific Y chromosome sequences (Doberman breed) as the reference, Fan et al. recently identified a set of nine male-specific Y chromosome scaffolds with a total length of 964 kb from the male red panda genome assembly (table S5) (31). Using the 964-kb male-specific Y chromosome scaffolds as the reference, we aligned the whole-genome resequencing reads of 18 male red pandas to the reference genome using BWA and then performed SNP calling using SAMtools and GATK. As a result, a total of 63 Y-SNPs were identified. Furthermore, we screened 22 Y-SNPs with confirmed polymorphism and good PCR/sequencing performance. Then, we genotyped these Y-SNPs for a total of 49 male red pandas. With the genotyping of more individuals, we found five additional Y-SNPs. As a whole, the dataset of 49 male red pandas with 27 Y-SNPs was used for subsequent paternal population genetics analysis (tables S2, S6, and S7).
We used the Assembly by Reduced Complexity method (32) to assemble mitochondrial genome with the published red panda mitochondrial genome as a reference (33) (GenBank accession: AM711897). First, the sequencing reads of each of the 65 red pandas were mapped onto the mitochondrial genome reference. Second, the mitochondrial genome reference was classified into multiple bins, and the alignment results were used to distribute reads into specific bins. Third, assembly was performed for each bin to produce contigs. Last, the initial reference was replaced with assembled contigs, and the above processes were iterated until stopping criteria have been met (32). The mitochondrial genome sequence used lastly excluded the highly repetitive sequences within the D-loop region.
We conducted PCA for whole-genome SNPs using the program GCTA v1.24.2 (34). A maximum likelihood phylogenetic tree was constructed by RAxML software (35) with the GTRGAMMA model and 100 bootstraps, and the ascertainment bias correction was performed to correct for the impact of invariable sites in the data. Ferret was used as the outgroup (36). Population genetic structure was inferred by ADMIXTURE v1.23 software (37) with default settings. We did not assume any prior information about the genetic structure and predefined the number of genetic clusters (K) from two to seven. We used POPART v1.7 (38) to construct a median-joining network for the Y-SNP haplotypes and mitochondrial genome haplotypes. We constructed the phylogenetic tree based on mitochondrial genomes of 15,238 bp (excluding the D-loop region) using BEAST v1.8.2 (39) with ferret as the outgroup. The best substitution model of GTR + I was selected on the basis of the Bayesian Information Criterion by ModelGenerator v0.85 (40). A strict clock rate was selected on the basis of the assessment of coefficient of variation. A total of 8 108 iterations were implemented with 10% burn-ins. The BEAST running results were assessed by Tracer v1.5 and were annotated by TreeAnnotator v1.10. We constructed the phylogenetic tree based on Y-SNPs data using the maximum likelihood method implemented in RAxML (35), with the ascertainment bias correction and ferret as the outgroup.
To reconstruct the detailed demographic history of each red panda population, we applied the simulation PSMC v0.6.4-r49 (41) to the whole diploid genome sequences, with the following set of parameters: -N 30 t 15 r 5 -p 4 + 25*2 + 4 + 6. We excluded sex-chromosome sequences of the red panda genome by aligning the red panda genome with the dog genome. We selected two to three high-depth sequenced individuals from each population for PSMC analysis (table S3). We estimated the nucleotide mutation rate of red panda using ferret as the comparison species and the following formula: = D g/2T, where D is the observed frequency of pairwise differences between two species, T is the estimated divergence time, and g is the estimated generation time for the two species (42). In this study, the generation time (g) was set to 6 years (26), the estimated divergence time was set to 39.9 Ma ago (15), and D was estimated to be 0.10558. On the basis of the above formula and the corresponding values, a mutation rate of 7.9 109 mutations per site per generation was estimated for the red panda. In addition, we performed BSP analyses based on mitochondrial genomes of 15,994 bp for two species separately, using BEAST v1.8.2. The best substitution model of HKY + I was selected by ModelGenerator v0.85. A strict clock rate was selected with a nucleotide substitution rate (43) of 1.9 108. A total of 8 108 iterations were implemented with 10% burn-ins. The BEAST running results were assessed, and the BSP plots were produced by Tracer v1.5.
We used the flexible and robust simulation-based composite-likelihood approach implemented in Fastsimcoal2 v2.5.2.21 (44) to infer species/population divergence and demographic history with the following parameters: -n 100000 -N 100000 -d -M 0.001 -l 10 -L 40 -q --multiSFS -C10 -c8. Because of the memory limit of Fastsimcoal2 running, we selected 55 individuals among 65 red pandas for simulation analysis (table S2). Four alternative population divergence and demographic models were explored. For each model, we ran the program 50 times with varying starting points to ensure convergence and retained the fitting with the highest likelihood. The best model was selected through the maximum value of the likelihoods. Parametric bootstrap estimates were obtained on the basis of 100 simulated data sets (table S9). In addition, we performed population-level admixture analysis for detecting gene flow among genetic populations using the TreeMix method (45) with the following running parameters: treemix bootstrap k 1000 se noss m 1~5.
For whole-genome data, the nucleotide diversity () (46) and Wattersons estimator (w) (47) of each genetic population were calculated using VariScan v2.0.3 (48). A sliding window approach was used with a 50-kb window sliding in 10-kb steps. We estimated the genetic diversity for the mitochondrial genome data of 15,994 bp and Y-SNPs data using DNASP v5.10.01 (49). To assess the LD pattern in red pandas, the correlation coefficient (R2) between any two loci in each genetic population was calculated using vcftools v0.1.14 (50). Parameters were set as follows: --ld window -bp 500000 geno -r2. Average R2 values were calculated for pairwise markers with the same distance.
We used ANNOVAR (51) to annotate and classify the effects of SNP variants on protein-coding gene sequences. Then, the coding sequence variants were classified as LoF, missense, and synonymous variants. LoF variant denoted variants with gain of a stop codon. The missense variants were further categorized as deleterious and tolerated missense mutations by SIFT 4G (52). We determined the ancestral allele at each SNP position through comparison with the ferret genome (36). To detect the genetic load of each red panda population, for each individual, we counted the relative proportions of homozygous ancestral, heterozygous, and homozygous derived alleles for LoF, deleterious, tolerated, and synonymous variants, respectively. Furthermore, we calculated the ratio of homozygous derived LoF variants (or deleterious variants) to homozygous derived synonymous variants and the ratio of nonhomozygous derived LoF variants (or deleterious variants) to nonhomozygous derived synonymous variants for each individual.
In general, positive selection gives rise to lower genetic diversity within populations and higher genetic differentiation between populations (53). The genetic differentiation index FST (54) and the average proportion of pairwise mismatches over all compared sequences (55) have been widely used to detect selection (53). To detect selection signals possibly associated with local adaptation, we used a sliding-window method (50-kb windows with 25-kb increments) to calculate the genome-wide distribution of FST values and ratios for the two species, implemented in vcftools v0.1.14. We applied z transformation for FST values and log2 transformation for ratios and considered the windows with the top 5% Z(FST) and log2( ratio) values simultaneously as the candidate outliers under strong selection. All outlier windows were assigned to corresponding SNPs and genes. We used the GeneTrail2 method (56) to perform KEGG pathway and GO term enrichment analyses for selected genes located in specific regions. Each significantly enriched category included at least two genes, and the hypergeometric test was used to estimate significance (P < 0.05).
Supplementary material for this article is available at http://advances.sciencemag.org/cgi/content/full/6/9/eaax5751/DC1
Fig. S1. PCA plot of red panda whole-genome SNPs data, with PC1, PC2, and PC3 explaining 28.5, 4.1, and 3.6% of the observed variations, respectively.
Fig. S2. Phylogenetic tree based on 41 mitochondrial genome haplotypes, showing two significant species lineages (A. fulgens and A. styani).
Fig. S3. Phylogenetic tree based on eight Y chromosome SNPs haplotypes, showing two significant species lineages (A. fulgens and A. styani).
Fig. S4. Bayesian skyline plot (BSP) analysis results based on mitochondrial genomes.
Fig. S5. Four alternative population divergence models for Fastsimcoal2 simulations, with the maximum estimated likelihood values shown.
Fig. S6. Residual fit from the maximum likelihood tree estimated by TreeMix.
Table S1. Summary of the morphological differences between the Himalayan and Chinese red pandas.
Table S2. Sample information for whole-genome resequencing, Y chromosome SNP genotyping, mitochondrial genome assembly, and Fastsimcoal2 analysis.
Table S3. Summary of whole-genome resequencing data for 65 red panda individuals that include the individuals for PSMC analysis.
Table S4. Summary of SNP calling based on 65 red panda individuals.
Table S5. Cross-validation error result for varying values of K in the ADMIXTURE analysis.
Table S6. PCR primer information for validating the six male-specific Y-scaffolds of red pandas.
Table S7. PCR primer information for amplifying the SNPs on the male-specific Y-scaffolds.
Table S8. Eight Y-SNP haplotypes identified from 27 Y-SNPs of 49 male red panda individuals.
Table S9. Confidence intervals of key parameters for the best population divergence and demographic model estimated by Fastsimcoal2.
Table S10. Genetic diversity of whole genome, Y chromosome, and mitochondrial genome for different species and populations of red pandas.
Table S11. The 146 genes under selection with top 5% maximum FST values and top 5% minimum 1/2 values in the Himalayan red panda (MH).
Table S12. Significantly enriched KEGG pathways for the 146 genes under selection in the Himalayan red panda (MH).
Table S13. Significantly enriched GO terms of biological processes for the 146 genes under selection in the Himalayan red panda (MH).
Table S14. The 178 genes under selection with top 5% maximum FST values and top 5% minimum 1/2 values in the Chinese red panda (EH-GLG, XXL-LS, and QL).
Table S15. Significantly enriched KEGG pathways for the 178 genes under selection in the Chinese red panda (EH-GLG, XXL-LS, and QL).
Table S16. Significantly enriched GO terms of biological processes for the 178 genes under selection in the Chinese red panda (EH-GLG, XXL-LS, and QL).
This is an open-access article distributed under the terms of the Creative Commons Attribution-NonCommercial license, which permits use, distribution, and reproduction in any medium, so long as the resultant use is not for commercial advantage and provided the original work is properly cited.
R. I. Pocock, The fauna of british india including ceylon and burma, in Mammalia, Volume II (Taylor and Francis, 1941).
C. Groves, in Red Panda: Biology and Conservation of the First Panda, A. R. Glatston, Ed. (Academic Press, 2011), pp. 101124.
Y. Gao, Fauna Sinica, Mammalia, Vol. 8: Carnivora (Science Press, 1987).
A. R. Glatston, Status Survey and Conservation Action Plan for Procyonids and Ailurids: The Red Panda, Olingos, Coatis, Raccoons, and their Relatives (IUCN, 1994).
Y. Shi, J. Li, B. Li, Uplift and Environmental Changes of Qinghai-Tibetan Plateau in the Late Cenozoic (Science and Technology Press, 1998).
A. Glatston, F. Wei, Than, Zaw, Sherpa, A. Ailurus fulgens. The IUCN Red List of Threatened Species 2015: e.T714A45195924 (2015).
T. M. Keane, T. J. Naughton, J. O. McInerney, Modelgenerator: Amino Acid and Nucleotide Substitution Model Selection (National University of Ireland, 2004).
M. Nei, Molecular Evolutionary Genetics (Columbia Univ. Press, 1987).
Posted in Genome
Comments Off on Genomic evidence for two phylogenetic species and long-term population bottlenecks in red pandas – Science Advances
Whole genome sequencing could be the next big thing for consumers – Genetic Literacy Project
Posted: at 1:17 am
Genome sequencing was once impossibly expensive. The Human Genome Project, an international effort to decode the human genome that launched in 1990, took 13 years and an estimated $2.7 billion to complete. Then, in 2007, DNA pioneer James Watson became the first person to get his genome sequenced for less than $1 million. Since then, the cost of genome sequencing has been decreasing at a rate faster thanMoores law.
Now,Nebula Genomics, a spinout of Harvard University co-founded by geneticistGeorge Church, is launching an at-home test for less than the price of the latest Apple Watch. At $299, Nebulas service analyzes a persons entire genetic code, known as whole genome sequencing.
Whether there is a mass market for whole genome sequencing remains to be seen. Gillian Hooker, president of the National Society of Genetic Counselors, says one hurdle is that many people just havent heard of whole genome sequencing or are skeptical of how useful the results will be for managing their health.
Right now, most people dont walk away with actionable information, she says. But that will likely change as scientists understanding of genetics evolves.
With the price getting increasingly cheaper, whole genome sequencing could soon replace the more limited genetic tests that dominate the market today.
Read the original post
Continue reading here:
Whole genome sequencing could be the next big thing for consumers - Genetic Literacy Project
Posted in Genome
Comments Off on Whole genome sequencing could be the next big thing for consumers – Genetic Literacy Project
Tel Aviv University researchers discover a non-breathing living animal – The Jerusalem Post
Posted: at 1:17 am
Life science researchers at Tel Aviv University (TAU) have stumbled upon a non-breathing animal, challenging current understanding of the animal world, according to a study published in the Proceedings of the National Academy of Sciences of the United States of America.The research, led by Prof. Dorothee Huchon of the School of Zoology at TAUs Faculty of Life Sciences and Steinhardt Museum of Natural History, detailed the 10-celled parasite organism called Henneguya salminicola that is found in the muscles of salmon. The research was supported by the US-Israel Binational Science Foundation, and conducted along with Prof. Paulyn Cartwright of the University of Kansas, and Prof. Jerri Bartholomew and Dr. Stephen Atkinson of Oregon State University."The parasites anaerobic nature was an accidental discovery," TAU said in a statement. "While assembling the Henneguya genome, Huchon found that it did not include a mitochondrial genome. The mitochondria are the powerhouse of the cell where oxygen is captured to make energy, so its absence indicated that the animal was not breathing oxygen." The animal itself, a "myxozoan relative" of jellyfish and corals, apparently gave up on breathing and consuming oxygen in order to produce energy, somewhere along its evolutionary track. Aerobic respiration was thought to be ubiquitous in animals, but now we confirmed that this is not the case, Huchon explains. Our discovery shows that evolution can go in strange directions. Aerobic respiration is a major source of energy, and yet we found an animal that gave up this critical pathway.Fungi, amoebas or ciliate lineages living in oxygen-poor environments abandoned the need to consume fresh air quite some time ago, after their evolutionary trajectories followed an anaerobic path. The findings allude to the possibility that the same type of occurrence could happen to an animal if the conditions are right."Its genome was sequenced, along with those of other myxozoan fish parasites," TAU said in a statement. Before the discovery, experts were unsure whether organisms within the animal kingdom could survive without oxygen, given that animals are "multicellular, highly developed organisms, which first appeared on Earth when oxygen levels rose." The findings are important for future evolutionary research.Its not yet clear to us how the parasite generates energy," Huchon said. "It may be drawing it from the surrounding fish cells, or it may have a different type of respiration such as oxygen-free breathing, which typically characterizes anaerobic non-animal organisms. It is generally thought that during evolution, organisms become more and more complex, and that simple single-celled or few-celled organisms are the ancestors of complex organisms.But here, right before us, is an animal whose evolutionary process is the opposite. Living in an oxygen-free environment, it has shed unnecessary genes responsible for aerobic respiration and become an even simpler organism.
Excerpt from:
Tel Aviv University researchers discover a non-breathing living animal - The Jerusalem Post
Posted in Genome
Comments Off on Tel Aviv University researchers discover a non-breathing living animal – The Jerusalem Post
Rules of life: From a pond to the beyond – National Science Foundation
Posted: at 1:17 am
Researchers explore how an organisms genome affects its ability to live in an extreme environment
The Lagunitas pond in the Cuatro Cinegas Basin of Mexico.
February 25, 2020
The Cuatro Cinegas Basin in the Chihuahuan Desert of Mexico was once a shallow sea. Some 43 million years ago, it became separated from the Gulf of Mexico. The basin is nutrient-poor and harbors a "lost world" of aquatic microbes of ancient marine ancestry.
Because of these characteristics, it is an invaluable place for researchers to study and understand how life may have existed on other planets in our solar system.
In a National Science Foundation-funded study published in the journal eLIFE, a team of researchers at Arizona State University conducted experiments in the basin.
Their goal was to shed light on how an organism's genome -- its size, the way it encodes information, and the density of information -- affects its ability to thrive in an extreme environment.
For their experiment, the scientists conducted field monitoring, sampling and routine water chemistry testing for 32 days in a shallow, nutrient-poor pond called Lagunita.
They installed mesocosms, or miniature ecosystems, that served as a control group and remained separate from the rest of the pond. They then added fertilizer that was rich in nitrogen and phosphorus to increase microbial growth in the pond.
At the end of the experiment, the scientists examined how the community in the pond changed in response to the additional nutrients, focusing on the organisms' ability to process biochemical information in their cells.
Ultimately, the researchers found that indeed a nutrient-enriched community became dominated by species that could process biochemical information at a faster rate, whereas the original low-nutrient community harbored species with reduced biochemical information processing.
"We were able to identify and confirm that there are fundamental genome-wide traits associated with systematic microbial responses to ecosystem nutrient status, without regard to the species identity of those microbes," says Jim Elser, an ecologist at ASU and paper co-author.
What this may suggest for life on other planets is that organisms, no matter where they are, need information-processing machinery fine-tuned to the key resources around them.
"This study provides new insights into how microbes adapt to different types of environments, and the tradeoffs they may face in doing so," says Doug Levey, a program director in NSF's Division of Environmental Biology.
Read more:
Rules of life: From a pond to the beyond - National Science Foundation
Posted in Genome
Comments Off on Rules of life: From a pond to the beyond – National Science Foundation
