Not exact matches
The DNA programming required to create
life capable of replicating in even the most
simple single
celled organism is far far more complex than anything mankind has ever built.
Do you know the mathematical impossibility that even one of these could randomly come into existance?Let alone all of the building blocks required for just a single
simple cell to come together to form any type of
living thing?There sure should be some blobs of fossilized transitions if evolution could happen.You people are real smart why don't you quit bashing Christians and quit believing the garbage you have been fed, and look up the evidence put forth by the Creation Research people.They have in fact proven creation down to a cellular level.Unlike evolution scientists who have no answers, but cleverly devised fables.Evolution is not even a very good fairy tale.Even if I didn't believe in God, Evolution is such a fools explanation of the origin of man that it takes just that to even consider it true.I understand though that you athiests will believe anything that allows you to love your sin and hatred of the one true God.
[242] The beginning of
life may have included self - replicating molecules such as RNA [243] and the assembly of
simple cells.
Scientists a century ago believed the smallest single
living cell was a
simple life form.
The consensus on the evolution of primitive
life is that
simple life forms (prokaryotes, organisms whose
cells lack a distinct nucleus) inhabited the Earth about 3 - 4 billion years ago, eukaryotic
cells (those with a nucleus which contains the genetic material) emerging 2 - 3 billion years ago.
Scientists have created artificial
life (
simple single
cell organisms) in the lab already.
«In its 4.6 billion years circling the sun, the Earth has harbored an increasing diversity of
life forms: for the last 3.6 billion years,
simple cells (prokaryotes); for the last 3.4 billion years, cyanobacteria performing ph - otosynthesis; for the last 2 billion years, complex
cells (eukaryotes); for the last 1 billion years, multicellular
life; for the last 600 million years,
simple animals; for the last 550 million years, bilaterians, animals with a front and a back; for the last 500 million years, fish and proto - amphibians; for the last 475 million years, land plants; for the last 400 million years, insects and seeds; for the last 360 million years, amphibians; for the last 300 million years, reptiles; for the last 200 million years, mammals; for the last 150 million years, birds; for the last 130 million years, flowers; for the last 60 million years, the primates, for the last 20 million years, the family H - ominidae (great apes); for the last 2.5 million years, the genus H - omo (human predecessors); for the last 200,000 years, anatomically modern humans.»
for the last 3.6 billion years,
simple cells (prokaryotes); for the last 3.4 billion years, cyanobacteria performing photosynthesis; for the last 2 billion years, complex
cells (eukaryotes); for the last 1 billion years, multicellular
life; for the last 600 million years,
simple animals; for the last 550 million years, bilaterians, animals with a front and a back; for the last 500 million years, fish and proto - amphibians; for the last 475 million years, land plants; for the last 400 million years, insects and seeds; for the last 360 million years, amphibians; for the last 300 million years, reptiles; for the last 200 million years, ma - mmals; for the last 150 million years, birds; for the last 130 million years, flowers; for the last 60 million years, the primates, for the last 20 million years, the family H - ominidae (great apes); for the last 2.5 million years, the genus H - omo (human predecessors); for the last 200,000 years, anatomically modern humans.
The essential difference between
living and non-
living matter consists in this: the
living cell synthesizes its own complicated specific material from indifferent or non-specific
simple compounds of the surrounding medium, while the crystal simply adds the molecules found in its supersaturated solution.
Evolution's claim that all
life descends from
simple one -
celled organisms is contradicted by every experiment to produce
life from non-
life.
We anticipate some sort of growth toward increased complexity: increasingly larger organic macromolecules, then the convergence of many macromolecules to constitute a
simple living system, either as a
cell with its protective wall and vital nucleus or as some functional analogue, then the convergence of many
cells to form larger organisms.
(1) The
simpler depends upon fewer specific conditions and has fewer, less demanding needs; human
life, for example, depends upon so many more factors than single -
celled marine
life does.
One -
celled microorganisms, in developing their metabolism, will depend in turn upon whatever macromolecules are available, so we should expect every world to have its own way of organizing
simple living systems.
Planetary
life started with the
simplest living cells and amoebae - like creatures, yet out of them, through increasing complexity, our own species eventually evolved.
The original
life cells could have easily been
simple enough to have spontaneously developed.
The doctrine of internal relations and the assertion of occasions in the empty space of
living cells still do not do justice to the reasons that complex entities can not be explained in terms of the
simpler ones of which they are composed.
Solve for us the question of the reasonableness of athiesm, where you get something (big bang) from nothing — there must be a first cause of everything; explain implications of the anthropic principle and the wildly unprobablistic likelihood that our universe could even form in such a fashion as to be capable of sustaining
life (which has, interestingly, your athiest heavy hitters (i.e. Dawkins, Schwartz, etc.) necessarily positing multiple universe theories to get around the near probablistic impossibility of all conditions be present at time of big bang for
life to be possible without acknowledgement of a divine designing hand guiding the process); explain The probablistic impossibility of non-irreducibly complex basic
cells (
life) coming together spontaneously (DNA,
cell membrane, etc), even the most basic,
simple forms of
life allowing for reproduction, metabolism, etc...
So we can also contemplate this same unfolding and unified purpose of Christ in our own
lives, from our conception as a
simple cell, ensouled by God in accordance with the Unity Law, to Baptism and entry into Christ in the Eucharist, through the years of growing up and formation in holiness and the spiritual
life — maybe through failure and re-conversion.
It is, of course,
simpler to say that individual
life begins at conception, but this is problematic because a single
cell can not be said to be a human.
Yet, whereas the
cells of bacteria and other microbes are small and
simple, all visible
life, including us humans, is generally made up of large and complex
cell types.
You play the game by choosing an initial pattern of «
live»
cells, and then watch as the configuration changes over many generations as the rules are applied over and over again (see «Take two
simple rules»).
«Looking at
live cell membranes is almost impossible, because the
cell membrane is not a
simple structure; there are a lot of glycoproteins as well as the extracellular matrix,» explains Sang - Joon Cho, chief scientist and director of R&D at Park Systems in Suwon, Korea.
Simpler kinds of
living organisms came first, and it took hundreds of millions of years of evolution on Earth to progress from single -
celled life forms to complex organisms like ourselves.
The unique ecosystems of Cuatro Cienegas may yield insights into what sparked the Cambrian transition, a pivotal time about 540 million years ago when
simple, single -
celled life developed into a wide variety of multicellular forms.
Complex phenomena — which we have so far only been able to study in
live animals - can now be investigated in
simple laboratory experiments using cultivated
cells,» says postdoc Hans Christian Cederberg Helms from the Department of Pharmacy.
Given the potential for
living systems to produce highly complex chemical compounds, researchers working with Michelle C.Y. Chang at the University of California, Berkeley (USA), aimed to manipulate the biosynthetic machinery in
cells to use
simple fluorinated building blocks to make new organofluorine target molecules.
Northwestern University scientists now have demonstrated a
simple but powerful tool that can detect
live cancer
cells in the bloodstream, potentially long before the
cells could settle somewhere in the body and form a dangerous tumor.
But in an Opinion paper published June 16 in Trends in
Cell Biology, researchers propose that new genomic evidence derived from a deep - sea vent on the ocean floor suggests that the molecular machinery essential to eukaryotic
life was probably borrowed, little by little over time, from those
simpler ancestors.
Though little is known about Loki, scientists hope that it will help to resolve one of biology's biggest mysteries: how
life transformed from
simple single -
celled organisms to the menagerie of complex
life known as eukaryotes — a category that includes everything from yeast to azaleas to elephants.
How does a single -
celled organism, one of the
simplest life forms on Earth, manage to satisfy its nutritional needs?
Genetic information inside
simple cells designed to mimic primordial
life has been copied, with the help of a chemical made from citric acid
Earth's first few miles of bedrock teem with
life, but scientists had long assumed that only
simple, single -
celled organisms could survive there.
Adding some complexity to the seemingly
simple life of a single -
celled organism, researchers have found that a green alga uses snippets of RNA to control its genes.
It also lacks the energy - generating mitochondria present in most
living things and digests food with fermentation enzymes found only in bacteria and other very
simple single -
celled organisms.
The authors say, «sNOOOpy is
simple and potentially applicable to a wide variety of
living cells.
Contact: 508-289-7139;
[email protected] WOODS HOLE, Mass. — Using a
simple «mirror trick» and not - so -
simple computational analysis, scientists affiliated with the Marine Biological Laboratory (MBL) have considerably improved the speed, efficiency, and resolution of a light - sheet microscope, with broad applications for enhanced imaging of
live cells and embryos.
These microbes, also referred to as «prokaryotes», are relatively
simple life forms, in contrast to the complex
cells that we, humans, are comprised of.
Delivery of Macromolecules into
Live Cells by
Simple Co-incubation with a Peptide.
The role and importance of lipids has not been studied thoroughly in
living cells, both due to technical limitations and the
simple fact that cellular lipids constitute a molecular array of overwhelming complexity.
On an evolutionary note, co-activators CBP and p300 are found only in multicellular organisms, and not more
simple one -
celled life forms.
All
living cells, from
simple yeasts to human brain
cells, regulate their rate of growth and their ultimate size and shape.
Ribose is a
simple sugar that occurs naturally in all
living cells.
Just as the number on the bathroom scale isn't always a
simple reflection of calories consumed vs. calories burned, the number of years you've
lived isn't always a reflection of your biological age (meaning the age of your
cells).
Year 6 Science Assessments and Tracking Objectives covered: Describe how
living things are classified into broad groups according to common observable characteristics and based on similarities and differences, including micro-organisms, plants and animals Give reasons for classifying plants and animals based on specific characteristics Identify and name the main parts of the human circulatory system, and describe the functions of the heart, blood vessels and blood Recognise the impact of diet, exercise, drugs and lifestyle on the way their bodies function Describe the ways in which nutrients and water are transported within animals, including humans Recognise that
living things have changed over time and that fossils provide information about
living things that inhabited the Earth millions of years ago Recognise that
living things produce offspring of the same kind, but normally offspring vary and are not identical to their parents Identify how animals and plants are adapted to suit their environment in different ways and that adaptation may lead to evolution Recognise that light appears to travel in straight lines Use the idea that light travels in straight lines to explain that objects are seen because they give out or reflect light into the eye Explain that we see things because light travels from light sources to our eyes or from light sources to objects and then to our eyes Use the idea that light travels in straight lines to explain why shadows have the same shape as the objects that cast them Associate the brightness of a lamp or the volume of a buzzer with the number and voltage of
cells used in the circuit Compare and give reasons for variations in how components function, including the brightness of bulbs, the loudness of buzzers and the on / off position of switches Use recognised symbols when representing a
simple circuit in a diagram
This product includes the following 46 topics: Physical Science ♦ Clouds ♦ Fossils ♦ Landforms ♦ Layers of the Atmosphere ♦ Layers of the Earth ♦ Natural Disasters ♦ Natural Resources ♦ Plate Tectonics ♦ Rock Cycle ♦ Rocks and Minerals ♦ Volcanoes ♦ Water Cycle ♦ Weather
Life Science ♦ Animal Adaptations ♦
Cell Structures (Organelles) ♦ Ecosystems ♦ Human Body Organs ♦ Human Body Systems ♦
Life Cycles ♦ Photosynthesis ♦ Plant Parts ♦ Six Kingdoms of
Life ♦ Macromolecules ♦ Microscope Parts ♦ DNA ♦ Classification and Taxonomy Physical Science ♦ Atomic Structure ♦ Circuits ♦ Electricity and Magnetism ♦ Electromagnetic Spectrum ♦ Elements, Compounds, and Mixtures ♦ Force and Motion ♦ Forms of Energy ♦ Lab Equipment ♦ Measurement Tools ♦ Periodic Table ♦ Properties of Matter ♦ Reflection and Refraction ♦ Scientific Method ♦
Simple Machines ♦ States of Matter ♦ Waves Space Science ♦ Solar System ♦ Constellations ♦ Moon Phases ♦
Life Cycle of Stars
Year 4 Science Assessments Objectives covered: Recognise that
living things can be grouped in a variety of ways Explore and use classification keys to help group, identify and name a variety of
living things in their local and wider environment Recognise that environments can change and that this can sometimes pose dangers to
living things Describe the
simple functions of the basic parts of the digestive system in humans Identify the different types of teeth in humans and their
simple functions Construct and interpret a variety of food chains, identifying producers, predators and prey Compare and group materials together, according to whether they are solids, liquids or gases Observe that some materials change state when they are heated or cooled, and measure or research the temperature at which this happens in degrees Celsius (°C) Identify the part played by evaporation and condensation in the water cycle and associate the rate of evaporation with temperature Identify how sounds are made, associating some of them with something vibrating Recognise that vibrations from sounds travel through a medium to the ear Find patterns between the pitch of a sound and features of the object that produced it Find patterns between the volume of a sound and the strength of the vibrations that produced it Recognise that sounds get fainter as the distance from the sound source increases Identify common appliances that run on electricity Construct a
simple series electrical circuit, identifying and naming its basic parts, including
cells, wires, bulbs, switches and buzzers Identify whether or not a lamp will light in a
simple series circuit, based on whether or not the lamp is part of a complete loop with a battery Recognise that a switch opens and closes a circuit and associate this with whether or not a lamp lights in a
simple series circuit Recognise some common conductors and insulators, and associate metals with being good conductors
Space Science: ♦
Life Cycle of Stars ♦ Moon Phases ♦ Space and Planets Earth Science: ♦ Clouds ♦ Erosion ♦ Fossils ♦ Landforms ♦ Natural Disasters ♦ Natural Resources ♦ Plate Tectonics ♦ Rocks and Minerals ♦ Rock Cycle ♦ Water Cycle ♦ Weather
Life Science: ♦ Animal Adaptations ♦ Biomes ♦
Cell Cycle ♦
Cell Organelles ♦ DNA ♦ Evolution ♦ Food Chains ♦ Genetics ♦ Habitats ♦ Human Body Systems ♦
Life Cycles ♦ Macromolecules ♦ Plants Physical Science: ♦ Atomic Structure ♦ Electricity ♦ Electromagnetic Spectrum ♦ Elements, Compounds, and Mixtures ♦ Force and Motion ♦ Forms of Energy ♦ Magnets ♦ Periodic Table ♦ Properties of Matter ♦ Reflection and Refraction ♦ Scientific Method ♦
Simple Machines ♦ Sound and Light ♦ States of Matter ♦ Thermal Energy
Sometime in the next ten years, if we «do» nothing at all, one of the
simplest ways in the world to make money will be to buy square kilometers of Arizona and New Mexico and West Texas, cover them with solar energy
cells hooked into matteries, and linked by ultra-high-voltage transmission lines to cities in cooler, water rich places where people want to
live.
So whether the problem is
cell phones, the internet or video games, technology is something that should make our
lives simpler.