Daily Archives: April 18, 2016

Second Amendment Sports – Bakersfield, CA – Yelp

Posted: April 18, 2016 at 3:44 pm

Specialties

Second Amendment Sports specializes in serving customers the entire package of what they need to feel prepared for going out into the field. We don't just merely SELL our wares. We like to evaluate, educate, and make helpful suggestions.

Our clerks will listen to what you need, and present solutions that will fulfill your specific needs.

We offer self defense training at every level and for different purposes. One of our goals in training is to mentally and physically prepare our students to find the most appropriate means to protect themselves. Our Training Division holds non-firearm courses and firearm courses of all levels.

Second Amendment Sports also takes care of customers AFTER the sale. We offer a lifetime warranty for brand new firearms, mount and boresight services, sight installations, offsite gunsmithing, archery pro shop services, and reel spooling.

Established in 1993.

Matt and Dana Janes started selling ammo from inside his father's storage container at David Janes Company. "We started with six cases of ammunition, re-invested it, and never looked back," Matt says.

..and he didn't look back. His business grew from cases of ammo in a corner to adding some long guns in a floor rack, then taking up an entire wall of the storage container to display all his guns. Matt and Dana logged thousands of hours of work into their business and sold guns at gun shows to get the business name out to the Kern County crowd.

In 1999, Matt left full time employment with his father, David Janes, to open up Second Amendment's own storefront across the street. In 2003, he doubled the retail floorspace to sell more goodies. In 2007, he opened up a second location in Tucson, Arizona.

Matt and Dana show no signs of slowing down! They divide their time between stores, in order to ensure that they are still providing customers with the best experience possible!

Matt Janes involves himself in the entire outdoor sports industry. He has hunted upland game and big game in many western states with firearms and bow. He has fished the entire Pacific Coast. He is a Martial Arms graduate, and has owned almost every firearm imaginable! Matt is an Eagle Scout. He also has extensive backcountry experience in the entire Upper Kern Plateau. In 2005, he was honored with the title of "2005 Kern County Sportsman of the Year."

"Raised with basic family values and many early outdoor opportunities, I stayed close to my desires while honing my business skills with my father/mentor. Then I took those family business and relationship skills and applied them to the outdoor industry. Continually surrounding myself with good people and loving family has allowed me to find a creative outlet at Second Amendment Sports. I appreciate all my association with you over time, and I hope to continue to share this passion with you!"

Continue reading here:
Second Amendment Sports - Bakersfield, CA - Yelp

Posted in Second Amendment | Comments Off on Second Amendment Sports – Bakersfield, CA – Yelp

Study: Lunar Colonization Could be Surprisingly Cheap …

Posted: at 3:43 pm

NASA could dramatically cut the cost of returning humans to the moon if it is willing to mine and sell the moon's natural resources, according to a study commissioned by the agency.

The Space Frontier Foundation-penned study encourages NASA to mine the moon's hydrogen for the "commercial production of cryogenic propellant". The report estimates that there are 10 billion cubic meters of water on the moon's poles -- equivalent to Utah's Great Salt Lake. The mining operation could potentially reduce the cost of sending humans to the moon by 90%.

First, however, NASA must send robotic scouts to confirm that the polar water is even harvestable. "This will be a complex operation requiring a period of growth, trial and error, failure, repair, and maintenance as the process matures in operations and procedures," the report concedes.

A lunar propellant production facility and fuel depot could be significantly beneficial to future missions to Mars, as well as routine launches carried out by the Department of Defense, according to the report.

Despite the dramatic proposed savings from propellent production, the overall cost of the lunar colony doesn't come cheap: NASA will still need to cough up nearly $40 billion to establish the colony.

"This is the way that America will settle the final frontier, save taxpayers money and usher in a new era of economic growth and STEM innovation," said Space Frontier Foundation's Chairman Jeff Feige.

Click here to read the full report

Learn more about lunar colonies:

More here:
Study: Lunar Colonization Could be Surprisingly Cheap ...

Posted in Moon Colonization | Comments Off on Study: Lunar Colonization Could be Surprisingly Cheap …

Genome – Deoxyribonucleic Acid (DNA)

Posted: at 3:42 pm

Deoxyribonucleic Acid (DNA)

We all know that elephants only give birth to little elephants, giraffes to giraffes, dogs to dogs and so on for every type of living creature. But why is this so?

The answer lies in a molecule called deoxyribonucleic acid (DNA), which contains the biological instructions that make each species unique. DNA, along with the instructions it contains, is passed from adult organisms to their offspring during reproduction.

Top of page

In organisms called eukaryotes, DNA is found inside a special area of the cell called the nucleus. Because the cell is very small, and because organisms have many DNA molecules per cell, each DNA molecule must be tightly packaged. This packaged form of the DNA is called a chromosome.

During DNA replication, DNA unwinds so it can be copied. At other times in the cell cycle, DNA also unwinds so that its instructions can be used to make proteins and for other biological processes. But during cell division, DNA is in its compact chromosome form to enable transfer to new cells.

Researchers refer to DNA found in the cell's nucleus as nuclear DNA. An organism's complete set of nuclear DNA is called its genome.

Besides the DNA located in the nucleus, humans and other complex organisms also have a small amount of DNA in cell structures known as mitochondria. Mitochondria generate the energy the cell needs to function properly.

In sexual reproduction, organisms inherit half of their nuclear DNA from the male parent and half from the female parent. However, organisms inherit all of their mitochondrial DNA from the female parent. This occurs because only egg cells, and not sperm cells, keep their mitochondria during fertilization.

Top of page

DNA is made of chemical building blocks called nucleotides. These building blocks are made of three parts: a phosphate group, a sugar group and one of four types of nitrogen bases. To form a strand of DNA, nucleotides are linked into chains, with the phosphate and sugar groups alternating.

The four types of nitrogen bases found in nucleotides are: adenine (A), thymine (T), guanine (G) and cytosine (C). The order, or sequence, of these bases determines what biological instructions are contained in a strand of DNA. For example, the sequence ATCGTT might instruct for blue eyes, while ATCGCT might instruct for brown.

The complete DNA instruction book, or genome, for a human contains about 3 billion bases and about 20,000 genes on 23 pairs of chromosomes.

Top of page

DNA contains the instructions needed for an organism to develop, survive and reproduce. To carry out these functions, DNA sequences must be converted into messages that can be used to produce proteins, which are the complex molecules that do most of the work in our bodies.

Each DNA sequence that contains instructions to make a protein is known as a gene. The size of a gene may vary greatly, ranging from about 1,000 bases to 1 million bases in humans. Genes only make up about 1 percent of the DNA sequence. DNA sequences outside this 1 percent are involved in regulating when, how and how much of a protein is made.

Top of page

DNA's instructions are used to make proteins in a two-step process. First, enzymes read the information in a DNA molecule and transcribe it into an intermediary molecule called messenger ribonucleic acid, or mRNA.

Next, the information contained in the mRNA molecule is translated into the "language" of amino acids, which are the building blocks of proteins. This language tells the cell's protein-making machinery the precise order in which to link the amino acids to produce a specific protein. This is a major task because there are 20 types of amino acids, which can be placed in many different orders to form a wide variety of proteins.

Top of page

The Swiss biochemist Frederich Miescher first observed DNA in the late 1800s. But nearly a century passed from that discovery until researchers unraveled the structure of the DNA molecule and realized its central importance to biology.

For many years, scientists debated which molecule carried life's biological instructions. Most thought that DNA was too simple a molecule to play such a critical role. Instead, they argued that proteins were more likely to carry out this vital function because of their greater complexity and wider variety of forms.

The importance of DNA became clear in 1953 thanks to the work of James Watson, Francis Crick, Maurice Wilkins and Rosalind Franklin. By studying X-ray diffraction patterns and building models, the scientists figured out the double helix structure of DNA - a structure that enables it to carry biological information from one generation to the next.

Top of page

Scientist use the term "double helix" to describe DNA's winding, two-stranded chemical structure. This shape - which looks much like a twisted ladder - gives DNA the power to pass along biological instructions with great precision.

To understand DNA's double helix from a chemical standpoint, picture the sides of the ladder as strands of alternating sugar and phosphate groups - strands that run in opposite directions. Each "rung" of the ladder is made up of two nitrogen bases, paired together by hydrogen bonds. Because of the highly specific nature of this type of chemical pairing, base A always pairs with base T, and likewise C with G. So, if you know the sequence of the bases on one strand of a DNA double helix, it is a simple matter to figure out the sequence of bases on the other strand.

DNA's unique structure enables the molecule to copy itself during cell division. When a cell prepares to divide, the DNA helix splits down the middle and becomes two single strands. These single strands serve as templates for building two new, double-stranded DNA molecules - each a replica of the original DNA molecule. In this process, an A base is added wherever there is a T, a C where there is a G, and so on until all of the bases once again have partners.

In addition, when proteins are being made, the double helix unwinds to allow a single strand of DNA to serve as a template. This template strand is then transcribed into mRNA, which is a molecule that conveys vital instructions to the cell's protein-making machinery.

Top of page

Last Updated: June 16, 2015

Excerpt from:
Genome - Deoxyribonucleic Acid (DNA)

Posted in DNA | Comments Off on Genome – Deoxyribonucleic Acid (DNA)