The Mystery
of Life on Earth and Origin of the Corona Virus
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lim ju boo
A Private Communication:
A medical
specialist friend whom I know since our student’s days at the university called
me over the phone last evening me for my opinion on the origin of the corona
virus that is currently causing a pandemic outbreak.
He asked if this
virus could have been artificially created, and if not, if I could enlighten
the scientific world especially the virologists and the public its origin as he
told me there are currently too many confusing claims, theories and conspiracy been circulated
over the social media.
I was quite
surprised at his question as I am just as doubtful and unclear as many others on its origin.
But I am
sure it was not artificially created at the Wuhan Institute of Virology in China
or anywhere else in the world. Neither
was it spontaneously generated by bats nor the pangolins as its origin is
unknown.
Furthermore bats or any living organisms can only produce its own body
cells and its own kind through
reproduction, and definitely no animal can generate or produce a virus out of its own body
If it was merely
carried or transmitted by bats then must have an origin somewhere. Unfortunately
we have no record or clue to its evolutionary origin or history.
However, as
someone familiar with the subject on the evolution of life on Planet Earth, I may be able to very
briefly explain how all life including viruses may have started
Here’s the scenario
on how all life may have started and flourished on Earth very briefly explained
with random samples taken in the timeline over the billions of years
Earliest
Life:
Evolutionary
biologists believe the first pre-life started around 4,000 million years ago
when what we call was the beginning of prebiotic chemistry.
Then about
200 million years later (3800 million years ago), the first chemical fossils -
the RNA world began to emerge.
It was in
this period that all life forms began as a virus through random chance of
synthesis of nitrogen compounds and sugars floating in the warm primordial
oceans to generate the first RNA molecule from which all viruses constitute
their genomic make-up. But it took a very long time for this random chance to occur.
That period may have taken 743 million years after earth was created 4.543
billion years ago.
The
accretion of earth took place between 4.5 to 4.4 billion (4500 – 4400 million)
years ago when the Universe was created from the Big Bang. That was around 13.8
billion years ago.
The first
DNA and protein life started only in 36,000 million years ago and the first
photosynthesis (autotrophy) began 3500 million years ago when Archaea and
bacteria split.
The oldest
large organism only surfaced in 575 million years ago, and the first insects
emerged 396 million years ago, with the insects being one of the most
successful that flourished in tremendous abundance and species
Earliest
Fossils:
Scientists
make use of preserved remnants of living creatures left behind called fossils
to make a study and draw conclusions.
Among the
earliest known fossils were the cnidarians, the group sea creatures that include
jellyfish, sea anemones and corals, which were dated to around 580 million years
ago though the fossil evidence has been disputed.
Then 5
million years later (575 million years ago), strange life forms known as the
Ediacarans began to appear and this persisted for about 33 million years.
Then another
5 million years later (570 million years ago) there was a genetic drift when a
small group known as the Ambulacraria breaks away from the main group of
deuterostomes.
This group
eventually became the echinoderms consisting of starfish, brittle stars and
their relatives, and two worm-like families called the hemichordates and
Xenoturbellida also began to emerge.
Then emerged
the sea lily, another echinoderm thought to be the “missing link” between
vertebrates (animals with backbones) and invertebrates (animals without
backbones). The sea lily came in between around this time.
But
fossilized animals appeared only about 565 million years ago.
Around 540
million years ago the first chordates – animals that have a backbone or at
least a primitive version of it surfaced among the deuterostomes.
Then arose the
sea squirts (tunicates) that begin their lives as tadpole-like chordates, but
metamorphose part of their lives as bottom-dwelling filter feeders somewhat
like a bag fastened to a rock.
Their larvae
still look like tadpoles today, somewhat suggesting their close relationship
with backboned animals.
The Cambrian
Explosion:
The suddenly
there was an explosion of various forms of life on Earth like myriads of
flowers blooming in the fields in Spring.
The Cambrian
Explosion, also called Cambrian Radiation happened around 535 million years ago,
but we are unsure why this explosion of life unexpectedly occurred? One reason we
think is our inability to find older fossils which may have occurred earlier.
But it was
not until 530 million years ago that the first true vertebrate (an animal with
a backbone) emerged. It probably evolved from a jawless fish that has a
notochord, a stiff rod of cartilage, instead of a true backbone.
The first
vertebrate is believed to look probably quite like a lamprey, hagfish or
lancelet. Around the same time, the first clear fossils of trilobites
surfaced.
These are invertebrates
similar in appearance to gigantic woodlice that grew up to 70 centimeters in
length.
These
creatures mushroomed in numbers in the oceans for the next 200 million years.
The next
scenario 10 million years later (520 million years ago) was the appearance of Conodonts
as another early form of vertebrate.
They probably look like eels.
Cambrian
Life was confined mainly to the sea, but there is some evidence the first steps
onto land were taken by the end of this Period since the Cambrian Radiation was
between 542 – 488 million years ago.
The
Evolution of Fish:
Marine life
like the evolution of fish began about 530 million years ago during the
Cambrian explosion. It was during this time that the early chordates developed
the skull and the vertebral column, leading to the first craniates and
vertebrates.
The first
fish lineages belong to the Agnatha, or jawless fish. Early examples include
Haikouichthys.
During the
late Cambrian, eel-like jawless fish called the conodonts (chordates resembling
eels), and small mostly armoured fish known as ostracoderms, made their first appearances.
Most jawless
fish are now extinct; but the extant lampreys may approximate ancient pre-jawed
fish.
The oldest
fossils found are around 3.48 billion years old (2)(3)(4).
Since most
of the early lives arose from the seas it would be easier to investigate how
fish and shellfish and marine life rose from the ancient waters
All that
needs to be done is to catch ancient fish living in deep waters, or shellfish
such as bivalves in shallow waters by merely collecting them from seashores or
from reefs, and analyzing them in a laboratory.
Alternatively
barnacles may be used to look at the evolutionary history.
A barnacle
is a type of arthropod constituting the infraclass Cirripedia in the subphylum
Crustacea, and is hence related to crabs and lobsters. Barnacles are
exclusively marine, and tend to live in shallow and tidal waters, and hence
easier to capture and collect for study.
These specimens
once collected can be preserved in suitable preservatives such as in saturated
salt solutions, in formalin or in alcohol and sent to a laboratory for analysis.
Such studies includes histology and microscopy which we shall briefly discuss
later.
The
Dinosaurs:
Millions of
years later only do land animals such as dinosaurs emerged. We shall use the
dinosaurs as an example to represent life in pre-historic eras partly because
they go between the reptiles and the warm-blooded birds and partly because the
dinosaurs are very late comers and are far easier to study from the fossil bones
they left behind, as well as they are
the ones most studied in evolutionary history.
Dinosaurs
are a diverse group of reptiles called the Dinosauria.
They first
emerged during the Triassic period between 243 and 233.23 million years ago,
though the exact origin and timing of their appearance is still being
investigated.
They grew
into the prevailing terrestrial vertebrates after the Triassic–Jurassic
extinction an event around 201.3 million years ago, and their supremacy
remained throughout the Jurassic and
Cretaceous periods.
Their fossil
records suggest that birds are modern feathered dinosaurs, having evolved
during the Late Jurassic epoch.
They went
extinct about 65 million years ago at the end of the Cretaceous Period, after
roaming the Earth for about 165 million years.
After the
dinosaurs disappeared, birds as we know
them today began to appear and they were the only dinosaur lineage to survive
the Cretaceous–Paleogene extinction event which took place approximately 65 -
66 million years ago.
I remember
when I was an undergraduate student in zoology between 1961 – 1964 (among many
other entirely different types of courses such as chemistry, physiology,
nutrition, food quality control, microbiology, biomedical sciences and medicine I studied later), one of our senior lecturer in zoology told us
birds are glorified reptiles as the dinosaurs were also reptiles.
That was
quite a surprising statement to me then since even in those years I knew that
reptiles were cold-blooded and sluggish, whereas birds are endothermic
(warm-blooded) animals, and maintaining endothermy is costly for the birds as
they use up no less than 90% of total metabolism just to maintain their higher
body temperature than all mammals.
Their body
temperatures are between 37.7 to 43.50 C, compared to those of
mammals whose body temperatures are between36 - 390C. This is part
of their metabolic adaptation during their evolution since they need to take
flight often over very long distances across oceans and seas almost non-stop
especially during their migratory periods to warmer climates.
Hence they
need to be very active with extremely high metabolic rates, compared to cold-blooded
reptiles.
But
evolutionary biologists now have gathered sufficient evidences to show that
birds are not just gloried reptiles but gloried dinosaurs.
However from
the evolutionary biology point-of-view dinosaurs can again be divided into avian
dinosaurs which are birds, and non-avian dinosaurs, which are all dinosaurs
other than birds.
Dinosaurs as
Birds:
There are
over 10,000 living species of birds, and they are the most diverse group of
vertebrates besides perciform fish.
Paleontologists
have identified there are over 500 distinct genera and more than 1,000
different species of non-avian dinosaurs in evolutionary history.
Dinosaurs
are represented on every continent by both surviving species of birds, and the
rest from fossil remains.
But before
birds were recognized as dinosaurs and glorified reptiles, scientists once
thought dinosaurs were cold-blooded.
However most
of the studies conducted since the 1970's, found that all dinosaurs were actually
active animals with warm metabolisms and several adaptations for social
interactions.
Demise of
the Dinosaurs:
Dinosaurs
first made their appearance about 225 million years ago, during the Triassic
period, and the last non-avian dinosaurs went extinct sixty-five million years
ago.
Many
theories have been proposed towards this mystery ranging from some kind of cataclysmic
event like an asteroid impacts, volcanic eruptions, or both.
One of the best
well-known theories for the demise of the dinosaurs is the Alvarez hypothesis,
named after the father-and-son duo Luis and Walter Alvarez.
In 1980, these
two father-son scientists proposed a
hypothesis that a meteor the size of a mountain slammed into Earth 66 million
years ago, filling the atmosphere with gas, dust, and debris that drastically cutting
off sunlight, altered the climate and reducing food supply by cutting off photosynthesis.
Their key
evidence to their theory was that an unusually high amount of the metal iridium
was found in the Cretaceous-Paleogene, or K-Pg, layer which is the geological boundary
zone that seems to cap any known rock layers containing dinosaur fossils.
Iridium is
relatively rare in Earth's crust but is more abundant in stony meteorites,
which led the Alvarezs to conclude that the mass extinction was caused by an
extraterrestrial object.
But
scientists like Manabu Sakamoto from the University of Reading (one of my alma
maters) and those from the University of Bristol have other theories.
Using
statistical analysis, they concluded that for 50 million years before even the
extinction of the dinosaurs, many other species were already going out of extinction
faster than new ones were emerging for reasons unknown.
But let us
not dwell into all these different theories on their disappearance mysteries.
Herbivorous
and Carnivorous:
Some dinosaurs
were herbivorous, others carnivorous. There were also evidences to propose that
dinosaurs like birds were egg-laying, and that they built nests too, a common
denominator shared by both avian and non-avian dinosaurs. This is some very
surprising findings in the life history of these creatures.
All these
findings among many, many more were part of the various investigations done in
evolutionary biology.
Actually the
evolution of life on Earth has a very long time line. Dinosaurs came long after
the Cambrian explosion or Cambrian radiation (1).
It was a
pre-dinosaurs event approximately 541 million years ago during the Cambrian
period when practically all major animal phyla started appearing in the fossil
record.
It lasted
for about 13 million years (7)(8)(9) to
25 million years (10) (11), and resulted
in the divergence of most modern metazoan phyla.(12) (13) (14) (15).
The question
people puzzlingly ask is, how do scientists and evolutionary biological experts
know all these scenarios took place billions of years ago?
The only way
is to collect fossil remains for laboratory analysis. Let’s briefly have a
look.
Laboratory
Studies:
The most
important method in the study how life evolved on Earth is to collect samples
of dead and living specimens in the field for study.
Normally preserved
remnants in the form of either trace,
tell-tale signs or impressions of any ancient living creatures or of life
called fossils, that represents some ancient living creatures from a past
geological age are collected for study
in a laboratory.
These could
be bones, shells, exoskeletons, stone imprints of animals or microbes, objects
preserved in amber, hair, petrified wood, oil, coal, and even remnants of DNA. These
collective remnants are known as the fossil record.
Paleontology
is the study of fossils: their age, method of formation, and evolutionary significance.
Specimens are usually considered to be fossils if they are over 10,000 years
old. (1). How are they investigated?
Morphology
and Histology:
Morphology
gives a general description and gross description and the anatomy of the sample.
This examination is first done before dissecting them.
Histology is
the study of the microscopic anatomy of cells, tissues, and organs as seen
through a microscope. It examines the correlation between structure and
function.
Normally this
entails dissecting the collected samples, embedding them in paraffin wax, and cutting
them with a microtome. The tissues are then stained for study under a
microscopy or even using other techniques of preparation for electron
microscopy.
The most common technique used before histology is embedding the tissues in paraffin wax or
plastic, then sectioning the block, mounting the thin slices on microscope
slides, and staining them to help distinguish one type of tissue from another.
Histology
allows evolutionary biologists to examine the inner structures of soft anatomy,
or to reconstruct the anatomy of species that are too small to dissect by hand.
Their structures may give clues how anatomical structures were evolved over the
millions of years.
Sedimentary Rocks:
Another
method to understand how ancient species were evolved is to use fossil evidence
as already briefly discussed. Fossils
are most often found in sedimentary rock.
Sediments
are sand or clay which settled at the bottom of a body of water. Over a period
of time, the layer of sediment is covered by overlapping new layers. As these layers
becomes heavier, the sediment solidify into sedimentary rock.
Dead
organisms can be concealed under new layers of sediment and or conserved in
sedimentary rocks. This process can generate fossils.
Electron
Microscopy:
Besides
light-transmission microscopy an electron microscope may also be used for sub-microscopic
detailed studies.
Electron
microscopy using beams of electrons instead of light. This gives a much higher magnifications where a specimen is needed to provide a much
more detailed information about a certain structure.
These high-energy
electron beams examine and photograph further details on the shells and skeletons
and anatomy or other parts of the specimen to examine their formation
Scanning
electron microscopy (SEM) provides
high-resolution images of outside surfaces, like sculpture, a hinge, or the
appearance of the siphons.
Transmission
electron microscopy (TEM) provides very fine details of cross sections of
tissues, such as sperm that are still under development, say in the specimen of
reproductive tract under study.
Molecular
Methods:
Another
method used in the investigation is DNA
or RNA isolation and their sequencing.
These are
very valuable methods to determine evolutionary pathways and relationships
among various species.
In some ways
DNA and RNA analysis can be more useful than gross morphology, since DNA is less inclined to actions of external forces such as food, temperature, and
the location in which the ancient specimens were found or collected.
Genomic
Sequencing:
Next comes
genomic analysis. The basic procedure in gene sequencing involves extracting
the DNA / RNA from the preserved specimen and purifying them
For instance
we can extract bones, shell or muscle fibers, skin, hair from a fresh sample or was already preserved in alcohol or in other preservative.
Scientists
then decides which area of the gene (DNA) that needs to be amplified by using Polymerase Chain Reaction (PCR).
This
technique makes extra copies of the desired gene, using chemical and heat
cycles. The amplification produces sufficient of the gene DNA for the sequencing procedure.
A PCR thermocycler
machine does sequencing using chemical and heat cycles to duplicate copies of
the gene sequence.
The result
is then read using a Gene Sequencer.
Some sequencer
machines use a laser to read a fluorescent "tag" attached to the DNA
fragments to produce a chromatogram.
The chromatogram
shows coloured patterns which are distinct zones of separated pigments of
unidentified DNA patterns.
There are
four bases of a DNA molecule, and these will be color-coded for easy identification,
such as red zone A (adenine), green T (thymine), black G (guanine), and blue C
(cytosine).
The
arrangements of these sequences are then compared with another sample with
similar or matching close biological lineages in an evolution tree.
Likewise,
unmatched sequencing bases may also showed up for comparison since their
genomic signatures maybe used for further phylogenetic analyses.
Other
Sequencing Techniques:
One method
in use since 2005 is the capillary sequencing but this has been progressively
displaced by high output sequencing technologies such as Illumina dye
sequencing, pyrosequencing, and SMRT sequencing.
All of these
technologies continue to employ the basic shotgun strategy, namely,
parallelization and template generation via genome fragmentation.
Other
technologies are emerging, including nanopore technology. Though nanopore
sequencing technology is still being refined, its portability and potential
capability of generating long reads are of relevance to whole-genome sequencing
applications
Phylogenetic
Analysis:
This is an analytical
method used to look at the hypothesis of correlations among species. This is
done by coding the various states of homologous characters called cladistics.
Scientists
use the anatomical traits and/or molecular sequences to determine a phylogeny.
Sequence of
ancestors of a particular lineage or history of an organism's lineage through
time can then be traced. This phylogeny is a hypothesis based on taxon or taxa.
In short it
is a method to determine heritable traits, such as DNA sequences or morphology
between species
Using this
analysis organism or group of organisms of the same class such as members of an
order, a family, genus, or species under study can then be identified by their
genomic characteristics and traits
Radiometric
Dating:
Another method
evolutionary biologists look at is the linages and the origin of a species by
using radioactive isotope tagging, called radiometric dating. This procedure
banks on radioactive isotopes to determine the age of a fossil in years.
Since radioactive
isotopes present in the body decay at a steady rate, scientists then looks at
the half-life of these isotopes.
The
biologist takes into account the time for half of the radioactive isotopes in a
sample to breakdown into nonradioactive isotopes. By knowing how much
non-radioactive isotopes were left gives the investigator clues to the age of
the fossil.
Carbon
Dating:
One form of
this analysis is called carbon dating. This technique is useful for fossils of
living organisms as they contain radioactive carbon-14.
The
disadvantage of carbon-14 dating is that carbon-14 has a comparatively short
half-life on the evolutionary scale.
Hence it may
only be useful for dating relatively later stage fossils remains that are no
older than 60,000 years old.
Alternatively,
longer life radioactive isotopes such as potassium-40 may be used to determine
the age of older fossils.
The
difficulty of using long-life isotopes is that they are found in rock, and not in
fossils.
Even then,
these long-life isotopes permit scientists to date layers of sedimentary rock
within which the fossils are embedded.
It all depends on what timeline and life forms we are searching.
All these
were determined using various methods including molecular clock in which
molecular differences are used to determine when two lineages of species
diverged later in the timeline of
evolution.
Read more:
https://www.newscientist.com/article/dn17453-timeline-the-evolution-of-life/#ixzz6NU7vM5Bm
https://www.newscientist.com/article/dn17453-timeline-the-evolution-of-life/#ixzz6NU7blLAO
https://www.newscientist.com/article/dn17453-timeline-the-evolution-of-life/#ixzz6NU7E3Yv9
https://www.newscientist.com/article/dn17453-timeline-the-evolution-of-life/#ixzz6NU6Qha3S
Having very
briefly described some of the analytical tools scientists use to determine a geological and biological time scale of Earth’s history,
they can then classify the various eons,
eras, and periods during which life evolved in order to rate of their emergence on Earth
Summary:
Life on
Earth has a very long history which took between 4.5 to 4.4 billion (4500 –
4400 million) years to emerge after the Universe was created from the Big Bang.
That event took place around 13.8 billion years ago.
Its origin of life itself is still unclear to us.
Many theories have been proposed, but none definitive.
The theory
of evolution is based on many studies and observations by scientists like Charles
Darwin from the University of Cambridge who went round the world in the HMS
Beagle with Captain Robert FitzRoy on a journey that took them 5 years.
Darwin also went to the Galapagos Islands and
observed the beaks sizes of finches which were a group of about 26 species of
passerine birds.
They are
well known for their remarkable diversity in beak forms and sizes and functions since these finches need to adapt to break open seeds of various sizes due to
seasonal variations.
Darwin then
published his world-renown theory of evolution “The Origin of the Species” Some
other studies on evolution were also conducted
by Jean-Baptiste Lamarck a French naturalist. But we shall not go all
the details.
In the study
of evolution and mystery of life on Earth biologists make use of fossils together
with histology, microscopy, isotope dating and phylogenetic analysis to look at
differences between species and determine
their evolutionary linkages.
Differences
between two similar species that became separate species may be due to various
environmental challenges causing them to adapt, separate and speciate
differently.
This causes
a genetic drift in biodiversity - either by what population geneticists called as
a “founder effect”, or a “bottleneck effect”.
There are
many other techniques that may also be used such as the use of mitochondrial
DNA analysis and also comparative anatomy to trace human ancestry and identification,
although human evolution is a separate subject that came last and very much
later.
However none
of the study techniques can be used to trace the origin of the corona virus
that is plaguing the world today.
This is
because in the thinking of this author this virus has never occurred in the
past with no genomic records available for comparison.
Unfortunately
my ignorant doctor friend asked me for the impossible. The closest link between
the Covid-19 virus is those found during
the emergence of SARS in 2003, MERS in 2012 all of which is believed to be the
same group of corona viruses, but none provide sufficient data or evidence
their origin except sharing the same genomic data.
Where did
they come from has been hotly debated and
unbelievable stories and theories being
circulated in videos and written text in their tens of hundreds among other conspiracies
including the virus being artificially created either in China or America.
We cannot
match anything, be they non-living viruses or pre-life molecules or any
organism that stands alone and has no previous records or evidence to compare.
We will not go into those presumptions for discussions.
This is
supposed to be a very brief and very simple account written in simple non-technical language for readers
to understand how evolutionary biologists
trace the evolution of life on
Earth over the few billions of years taking random samples of eons, periods, eras on which
various life forms appeared.
Hence we
shall not go too much into all the timeline of biological evolution as from the
very beginning this author has to account for its history to be written in less
than a 6,000 words, else he has to write a comprehensive account on evolution
in the form of a text book between 500 – 800 pages with data, graphs diagrams,
and photographs all thrown in. We will not do that for easy reading.
This
Covid-19 virus as well as those SARS virus may have originated from outer
space. For this separate theory, kindly refer their origin by this author here:
Is SARS
Virus A Harbinger from Another World:
Also on the mystery
on Covid-19 here:
2020: The
War of the Worlds: Earthlings vs. The Corona Virus. Who will Win?
Thank you
for your valuable time and effort reading – jb lim
(4,854 words: 25 pages)
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