About Martian Bacteria … by Alice B. Clagett ..

Revised on 9 July 2017; originally published on 30 November 2016 

  • How Much of Our Body Is Bacteria? One-Half of It
  • Bacterial Life on Mars Today
  • What Bacteria Look Like
    • How the Martian Bacteria See Themselves
    • How We See the Martian Bacteria
  • How a Bacterium Reproduces
    • Asexual Fission
    • Plasmids
    • Sexual Reproduction Among Bacterial: Conjugation
  • Mobile, Self-Splicing Group II Introns in Bacteria
  • Are Plasmids and Mobile Group II Introns the Means by Which Bacteria Bioengineer Humans?
  • How and What Do Bacteria Eat?
    • What Bacteria That Colonize Other Life Forms Eat
    • What ‘The Ancient Ones’ Eat
    • How Bacteria Arrange Place Seating for Dinner
  • Facts to Support Martian Claims of Their Space Exploration Program
  • How to Optimize the Martian Population That Colonizes Our Colon

Dear Ones,

I’ve done some research on bacteria. It appears they are from Mars. I’ve found tentative substantiation of their assertion, through telepathy, at which they are adept, that they are expert at space travel, at microminiaturization and at human bioengineering. I’ll paraphrase a sentence or so of each source (that which I found most interesting) and then provide the source.

HOW MUCH OF OUR BODY IS BACTERIA? ONE-HALF OF IT

Folks used to think there were 10 bacteria and various other microbes per human cell in our bodies. This article suggests it’s more like 1.3 bacteria to 1 human cell, and that most of the bacteria reside in the colon. So we’re less outnumbered than was previously thought.
–Adapted from “Scientists bust myth that our bodies have more bacteria than human cells: Decades-old assumption about microbiota revisited,” by Alison Abbott, from http://www.nature.com/news/scientists-bust-myth-that-our-bodies-have-more-bacteria-than-human-cells-1.19136 

BACTERIAL LIFE ON MARS TODAY

There’s a meteor from Mars that landed in Antartica some 13,000 years past. Scientists are pretty sure what they found in it was fossilized bacteria from Mars. The age of the bacteria was 3.6 billion years. Scientists also found evidence that Mars had water on it long ago. This is important, as the presence of water is thought necessary for bacterial life to flourish.
–Adapted from “USCB Science Line: Is there really life on Mars? What evidence is there that there may or may not have been life on Mars?” http://scienceline.ucsb.edu/getkey.php?key=2986

Alfred McEwen, a professor at the University of Arizona, feels there are water pools below the surface of Mars, and that Martian bacteria may thrive there. He points out that microbes call the harsh environment of the Antarctic lakes home as well.
–“Life on Mars STILL exists beneath the surface, claims top Nasa scientist: HIDDEN lakes on Mars are likely to contain some form of life, a leading expert has claimed, by Sean Martin, published 11 July 2016 16:20, http://www.express.co.uk/news/science/688359/Life-Mars-claims-Nasa-scientist-alien-red-planet

WHAT BACTERIA LOOK LIKE

How the Martian Bacteria See Themselves. According to my clair intel, the Martians are disdainful of our depictions of them. Their own vision of their species is of the great, sentient light with which they light up our Earth.

How We See the Martian Bacteria. Here is a standard image of a bacterium; the flagellum, a whip-like appendage, provides motility. Some bacteria have several flagella.

prokaryote_cell-svg
“Structure and contents of a typical gram-positive bacterial cell (seen by the fact that only one cell membrane is present).” “This vector image is completely made by Ali Zifan – Own work; used information from Biology 10e Textbook (chapter 4, Pg: 63) by: Peter Raven, Kenneth Mason, Jonathan Losos, Susan Singer · McGraw-Hill Education. A diagram of a typical prokaryotic bacteria cell,” from https://en.wikipedia.org/wiki/Bacteria#/media/File:Prokaryote_cell.svg … CC BY-SA 4.0

Here’s an image of a bacterium with several flagella: http://www.daviddarling.info/images/bacterium_structure.gif

Here is Boxtail’s incredible, and apparently clair, depiction of a bacterium on DeviantArt: http://orig11.deviantart.net/2e75/f/2015/238/a/1/bacterium_by_boxtail-d978t0c.png ..

HOW A BACTERIUM REPRODUCES

A bacterium can reproduce either asexually or sexually. The former is called ‘asexual fission’ and the latter ‘conjugation’.

Asexual fission in a bacterium is simply a case of replication of the original DNA, then splitting of the bacterial cell into two separate cells. There is no change in the DNA from the parent cell to the offspring cell:

binary_fission_2-svg
“1: The bacterium before binary fission has the DNA tightly coiled. 2: The DNA of the bacterium has replicated . 3: The DNA is pulled to the separate poles of the bacterium as it increases size to prepare for splitting.(This is missing the fact that the DNA attaches itself to the inner cell wall) Ergo Diagram not completely correct! 4: The growth of a new cell wall begins the separation of the bacterium. 5: The new cell wall fully develops, presenting in the development of down syndrome, resulting in the complete split of the bacterium. 6: The new daughter cells have tightly coiled DNA, ribosomes, and plasmids.”
–Author Ecoddington, 14 22 May 2014, 14:17:40 … from Wikimedia, https://commons.wikimedia.org/wiki/File:Binary_Fission_2.svg …  This file is licensed under the Creative Commons Attribution-Share Alike 3.0 Unported license.

Asexual fission allows bacteria to reproduce very quickly, provided that they have sufficient food and the right temperature. For example Escherichia coli can reproduce once every 20 minutes. Reproducing in this way, one bacterium can generate 16.7 million offspring.
–from “Microbiology Online: Bacteria,” http://www.microbiologyonline.org.uk/about-microbiology/introducing-microbes/bacteria 

A bacterium can also reproduce sexually, a process that involves conjugation, or exchange of chromosomal material. Before discussing this method of reproduction, though, let’s take a look at the topic of plasmids:

Plasmids. “A plasmid is a small DNA molecule within a cell that is physically separated from a chromosomal DNA and can replicate independently. They are most commonly found in bacteria as small circular, double-stranded DNA molecules; however, plasmids are sometimes present in archaea and eukaryotic organisms. In nature, plasmids often carry genes that may benefit the survival of the organism, for example antibiotic resistance. While the chromosomes are big and contain all the essential genetic information for living under normal conditions, plasmids usually are very small and contain only additional genes that may be useful to the organism under certain situations or particular conditions. Artificial plasmids are widely used as vectors in molecular cloning, serving to drive the replication of recombinant DNA sequences within host organisms.”
–from “Plasmids,” in Wikipedia, https://en.wikipedia.org/wiki/Plasmid

Here’s an image of plasmid replication:

685px-plasmid_replication_english-svg
“Description : This image shows a line drawing that compares the activity of non-integrating plasmids, on the top, with episomes, on the bottom, during cell division. The upper half of the image shows a bacterium with its chromosomal DNA and plasmids dividing into two identical bacteria, each with their chromosomal DNA and plasmids. The lower half of the image shows a bacterium with its chromosomal DNA, but with an episome. Next to this bacterium, we see the same bacterium, but after the episome has integrated into the chromosomal DNA and has become a part of it. This second bacterium now divides into two bacteria identical to it, each with an episome integrated into it.”
–Author: User:Spaully , 17:12, 9 May 2007 (UTC), from Wikipedia, https://commons.wikimedia.org/wiki/File:Plasmid_replication_(english).svg … This file is licensed under the Creative Commons Attribution-Share Alike 2.5 Generic license.

Sexual Reproduction Among Bacterial: Conjugation

Bacteria can also reproduce sexually, by a method known as conjugation. This method involves transfer of genetic material, contained in a plasmid, by one bacterium to another bacterium:

conjugation-svg
“Schematic drawing of bacterial conjugation. Conjugation diagram 1- Donor cell produces pilus. 2- Pilus attaches to recipient cell, brings the two cells together. 3- The mobile plasmid is nicked and a single strand of DNA is then transferred to the recipient cell. 4- Both cells recircularize their plasmids, synthesize second strands, and reproduce pili; both cells are now viable donors.”
–Author Adenosine , 16 September 2009 … in Wikimedia, https://commons.wikimedia.org/wiki/File:Conjugation.svg … CC BY-SA 3.0

MOBILE, SELF-SPLICING GROUP II INTRONS IN BACTERIA

These are RNA molecules that can move genetic elements from one cell to another. These Group II Introns are found in eucaryotes, plants, and were found to be self-splicing in bacteria in 1993. Since then, these introns have been used by humans in gene splicing research.

ARE PLASMIDS AND MOBILE GROUP II INTRONS THE MEANS BY WHICH BACTERIA BIOENGINEER HUMANS?

Plasmids and Mobile Group II Introns may be the means by which Martian bacteria genetically bioengineer their human ‘space stations’ … i.e., our human bodies.

Do bacteria, as they have clair conveyed, contain genetic material replicating their human hosts, to prevent their being attacked by the human immune system? If so, then there may be sufficient resonance between the bacterial DNA and RNA, and the human host DNA and RNA, for bacterial-human plasmid and intron transfer to take place.

This might explain the rapid evolution of life on Earth, not just for humans, but also for all animals co-tenanted by bacteria. (xxx

HOW AND WHAT DO BACTERIA EAT?

Most bacteria absorb food through channels in the walls of their cells. A few strains of bacteria photosynthesize food from sunlight.

What Bacteria That Colonize Other Life Forms Eat. When they’re in our colon, or the colon of many other life forms on Earth, they eat the food we have eaten.

What ‘The Ancient Ones’ Eat. There are also non-colonizing strains of bacteria … called by the colonists ‘The Ancient Ones’. These rough it outside of a protective life form. They are found everywhere on Earth, being much more successful at habitat adaptability than humans. This has partly to do with their dietary adaptability.

Thus, bacteria have been found that eat nuclear waste, crude oil, arsenic, caffeine, and steel. Also [not mentioned] wood.
–adapted from “10 Surprising Things That Bacteria Like to Eat,” by Keith Veronese5/24/12 1:00pm , http://io9.gizmodo.com/5908318/10-surprising-things-that-bacteria-like-to-eat 

How Bacteria Arrange Place Seating for Dinner. Sometimes bacteria eat solitarily. Or they may get together to eat in, in twos, chains, or squares.
–Adapted from “Reference: What Do Bacteria Eat?” https://www.reference.com/science/bacteria-eat-c67ad4f929d0d722 

FACTS TO SUPPORT MARTIAN CLAIMS OF THEIR SPACE EXPLORATION PROGRAM

That bacteria are able to secrete acid to dissolve rocks may account for their continuing success in the Mars habitat, where they may need to burrow through rock to get from one pool of water to another. This rock-dissolving ability also accounts for the presence of fossilized bacteria in the Antarctic meteorite discussed above. It further brings up the prospect that meteorites may have offered protection to them in their travels through space on meteorite ‘space ships’.
–adapted from “10 Surprising Things That Bacteria Like to Eat,” by Keith Veronese5/24/12 1:00pm , http://io9.gizmodo.com/5908318/10-surprising-things-that-bacteria-like-to-eat 

That bacteria can remain dormant for 40 million to perhaps 86 million years supports their reports of space travel as well. For instance:

“According to scientist Dr. Steinn Sigurdsson, “There are viable bacterial spores that have been found that are 40 million years old on Earth — and we know they’re very hardened to radiation.”[82] (2)

And when Aarhus University of Denmark extracted deep sedimentary cores from the ocean in 2009, they found bacteria that had remained almost completely dormant for 86 million years.
–Bacterial dormancy information adapted from Ibid.

HOW LONG BACTERIA HAVE BEEN ON EARTH

Telepathically, I’ve heard that bacteria on Mars first found out about life on Earth very long ago. A volcano erupted on Mars, and spewed volcanic ash so high that some bacteria cast up along with the ash were able to telepathically contact those beings that inhabited the ‘Primordial Soup’ on ancient Earth. (3) According to my intel, these beings were sentient and telepathic, but considered by the Martians to be crude life forms (upon which they as a species looked down).

Then, according to my intel, ‘others’ (?) helped them get to the space ships (meteorites?) that bore them to Earth. In the beginning, they say, there were only two bacteria that landed on Earth; from all these, the ‘Ancient Ones’ and the Life-Form Colonial Martians are derived.

Image: Timeline of Arrival of Life Forms on Earth: https://threepointeightbillionyears.files.wordpress.com/2013/03/life-timeline-4.jpg ..

Above is a link to a pretty good image of the timeline of the arrival of life forms on Earth. It appears that Earth formed about 4.65 billion years ago.

According to Wikipedia, the Primordial Soup formed about 3.8 to 3.55 billion years ago. I believe it must have formed earlier than this, as Martian bacteria appeared on Earth about 4 billion years ago, and according to Martian history, they contacted the Primordial Soup before sending an expedition to colonize Earth.

According to Wikipedia, bacteria, along with archaea (single-celled organisms without a cellular nucleus or organelles), (4) were the dominant life form on Earth for about 3 billion years. A very long time. (5)

In the beginning, bacteria looked very different from today. Here is an image of a cyanobacteria (blue-green algae) from 1 billion years ago: http://www.ucmp.berkeley.edu/bacteria/micro5small.gif ..

HOW TO OPTIMIZE THE MARTIAN POPULATION THAT COLONIZES OUR COLON

Eat cruciferous vegetables such as broccoli, bananas, beans, Jerusalem artichokes, blueberries, polenta, kimchee or sauerkraut, and tempeh.

Image of these foods: http://www.pcrm.org/sites/default/files/pdfs/health/food-and-gut-bacteria-infographic.pdf

Also, doing this activation of light will still the telepathic tempest and optimize timelines for all life-forms within us and outside our bodies:

“Activation of Light for Our Solar System,” by the Hathors, through Alice, https://iamofthestars.com/2016/11/28/activation-of-light-for-our-solar-system-by-the-hathors-through-alice/

In love, light and joy,
I Am of the Stars

THE COMPLETE MARTIAN ARCHIVES

For the complete Martian Archives, see: “The Martian Archives,” by Alice B. Clagett *: http://wp.me/p2Rkym-7sz ..

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FOOTNOTES

(1) “The Law of One: The Ra Material” speaks of how the human species was altered genetically by the Earth Martians, so that its evolution from 2D to 3D proceeded by leaps and bounds, rathere than gradually. See “The Law of One,” Session 14, question-answer 3:  14.3 … or search for this question-answer here: http://www.lawofone.info/results.php?q=Mars

1D (the first dimension, or ‘density’ as it is termed in “The Law of One”) is the density in which a planet solidifies. See “The Law of One,” Session 82, question-answer 13:  82.13

2D (the second dimension or density) is the density of minerals, of higher plant and animal life, lacking self-awareness; see “The Law of One,” Session 9, question-answer 14:  9.14  and Session 19, question-answer 2:  19.2

3D is the density of sentient, self-aware life forms. For more on this, see “The Law of One,”  Session 13, question-answer 21: 13.21

Or see these question-answers at http://www.lawofone.info/results.php?q=second+density

(2) from “Bacteria,” in Wikipedia, https://en.wikipedia.org/wiki/Bacteria … Text is available under the Creative Commons Attribution-ShareAlike License; additional terms may apply.

(3) “Primordial soup” is a term introduced by the Soviet biologist Alexander Oparin. In 1924, he proposed a theory of the origin of life on Earth through the transformation, during the gradual chemical evolution of particles that contain carbon in the primordial soup.

“Biochemist Robert Shapiro has summarized the ‘primordial soup’ theory of Oparin and Haldane in its “mature form” as follows:[1]

  1. “Early Earth had a chemically reducing atmosphere.
  2. “This atmosphere, exposed to energy in various forms, produced simple organic compounds (“monomers“).
  3. “These compounds accumulated in a “soup”, which may have been concentrated at various locations (shorelines, oceanic vents etc.).
  4. “By further transformation, more complex organic polymers – and ultimately life – developed in the soup.”
    –from “Primordial Soup,” in Wikipedia, https://en.wikipedia.org/wiki/Primordial_soup , Text is available under the Creative Commons Attribution-ShareAlike License; additional terms may apply.

(4) “The Archaea (Listeni/ɑːrˈkə/ or /ɑːrˈkə/ ar-kee or ar-kay) constitute a domain and kingdom of single-celled microorganisms. These microbes (archaea; singular archaeon) are prokaryotes, meaning that they have no cell nucleus or any other membrane-bound organelles in their cells.” –from “Archaea,” Wikipedia, https://en.wikipedia.org/wiki/Archaea

(5) The bacterial fossil record extends back more than 3.5 billion years. See “Microbe Magic,” http://microbemagic.ucc.ie/inside_guts/more_info/bacteria.html

Creative Commons License
Except where otherwise noted, this work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.

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Mars, Martians, bacteria, star brethren, asexual fission, conjugation, plasmids, mobile introns, Martian bioengineering, exobiology, Martian space exploration, Martian telepathy, Martian reproduction, Martian habitat adaptability, group II introns, primordial soup,

One thought on “About Martian Bacteria … by Alice B. Clagett ..

  1. Pingback: What Martians Love: The Song of the Leonids, the Wisdom of the Elohim … by Alice .. | I Am of the Stars

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