DNA Replication, mRNA Transcription, and Ribosomal Translation: The inter complexity of nucleic polymer and protein synthesis as evidence of the Cell Principal
The Cell Principal from the time of Robert Hooke (1665), Mathias Schleiden (1838), and Theodore Schwann (1839) until now in biology has been: First, "That all living things are made up of living units called cells and cell products," and Second, "That all cells come from pre-existing cells." 1. That this fundamental principal of biology is apparently contradicted in the fundamental principal of evolution (i.e. that cells evolved by random chance out of decomposition and solution of inorganic elements in the primordial sea.) is not widely admitted by current literature in education or the sciences. The notion that simple cells could evolve in some primordial environment, and that given great amounts of time, could also change into more complex forms, forms to which the cell principal might then apply to, seems to be the dogma of the day.
That notion, perhaps, was credible between 1860 and the early 1900's but, since the 1950's, with the advances in molecular biology, it seems obviously outdated and unduly ridged. As microscopy advanced with resolutions down into the angstrom scale and techniques that cryogenically paused molecular operations in process, the observational field in biology made a quantum leap. While those techniques combined with the DNA structural breakthroughs of Watson and Crick in 1953, molecular research and cytology was discovering a greater complexity than ever before imagined. There is no such thing as a simple cell. In fact this paper addresses a rather tiny portion of that complexity, perhaps a 10 billionth part, if that, and yet, this little part's complexity, as complexly as we now know it, is far beyond our collective scientific scope. Though we have much systematic, descriptive and analytic elaboration, there are more questions and mysteries than ever before. The ounces we have come to know provoke tons of research into that which we have come to question.
What do we know? The simplest statement of the DNA/RNA/Protein inter complexity is: Precision DNA polymers and precision molecular protein machines make RNA strands, and these precision strands working together with other precision protein machines make protein and protein machines. Copying DNA is incredibly complex, and yet it has to be done to perpetuate life. The instructions for making the protein machines are encoded in the DNA, which code is useless without the machines; of course the machines cannot be made without the instructions in the DNA. The precise sequential encoding and sequential protein construction involved in this process is in the order of tens of thousands, if not millions. The most obvious inference in this chicken and egg scenario is the confirmation of the Cell Principal, and an equal rejection of the Evolution Principal. Only a living cell and cell products can do the work and make the things of living cells: all RNA has come from pre-existing DNA and all Protein machines from pre-existing machines. The first cells had it all, because it's obviously all or nothing. And the random probability of systems ordered this complexly is virtually zero. This is the current scientific evidence, and it is evidence of design and intelligent construction and confirms the thesis that these organisms must have been made complete from the start, and moreover, each according to its kind.
Helicase and polymerase are two of the complex machines involved in replicating DNA and transcribing DNA into RNA. Next to these are the ribosomes, bi-structural protein complexes that read the messenger RNA (mRNA) strands and construct the encoded protein structures out of their individual amino acid parts gathered up by their individual transfer RNA (tRNA) carriers. The ribosomes thus translate the coded information into sequentially peptide bonded amino acids making complexly folded proteins. Ribosomal structures, as well as Helicase and polymerase structures, are encoded in DNA, and that is how they have come into being since the creation. But, quite obviously, the first of their kinds were created complete from the start; at least that is what the evidence indicates. The first cells must have had it all.
DNA Complexity (deoxyribonucleic acid)
DNA is a double helical polymer composed of deoxyribos sugar, phosphate, and the four nucleic bases adenine, thymine, cytosine, and guanine.2 The sugar/phosphate iterations form the two strands along both sides, and joining the opposed sides like runs on a ladder are two paired base molecules. Each sugar/phosphate side member having one of the bases bonded to the sugar group toward the side of the polymer and bonded toward the middle to its paired base counterpart, (adenine A to thymine T, cytosine C to guanine G: A/T or T/A and C/G or G/C.) The overall acidic properties of the polymer are attributable to the phosphate groups along its two sides. The fundamental element in this spiraling helix is the nucleotide which is one sugar/phosphate group with its unpaired base attached. A 16 inch strand is nearly 500 million times longer than its 2 nanometer width and may have more than 200 million nucleotide pairs. Human DNA in 46 chromosomes has about 3,165 million base pairs.
When this ladder is split down the middle separating the paired bases, two strands are expressed that constitute a 4X code at each nucleotide: A, T, C, or G, every three nucleotides of which representing a coded word of 64X possibilities. With some duplication the 20 bio-amino acids are represented with their own words along with some control words that encode operations essential to the replication, transcription, and translation devices that utilize this code for highly specific work. These 64 words have been experimentally demonstrated, with their individual amino acids and operations identified.3. But whether this is the sole extent of the sequences, or rather the only level of meaning is a question. Transfer RNA, (tRNA), having from 60 to 95 nucleotides which also must be transcribed off sequential DNA locations, has at least 20 different multi-word expressions; what else? What about the many ribonucleic protein structures, (RNP), e.g. Vaults and Ribosomes? Where are their structural RNA parts encoded? Lastly there are many external factors and controls that operate on DNA sites suitable to their influence: some are known; how many are not? Moreover, as DNA twists like licorice two groves are expressed where the active sites on the paired bases are presented in the major and minor groves. How many cell processes and cellular machines might utilize this structured information?
The packaging of DNA to fit into and be useful within the nucleus of cells is another wonder. First the twisting of the strand reduces its absolute length, but coiling twice around 8 histone proteins at precise points all along its length forms an 11 nanometer “string of pearls,” called a nucleosome string. This string is again coiled and, by the 9th histone protein, bound in solenoids of twisting groups of 6 to 8 nucleosome forming the 30 nanometer fibers called chromatin.4
The inter working of histone and DNA increases the complexity significantly in all other operations DNA is involved in. All operative factors network with these packaging states and coordinate their functions. Under meiosis and mitosis the DNA is coiled and folded more, but these above are normal DNA states during interphase where most cellular life work is done.
In any living organism all of its complexity from beginning to end is encoded in its DNA. And all that information is useless without the rest of that cell or cells. It has been said, that if the information in a teaspoon full of DNA were written into paperback books, the stack would reach from the earth to the moon and back 400 times. That is a lot of complexity in a very little package, but without a ribosome it is gibberish, useless.
Ribosomal Complexity
It takes a great deal of nonscientific, dogmatic inflexibility to believe that something as complex as a ribosome and yet as essential to all cellular life, could come into being on its own. The parts of this machine must not only all be there for it to do its job, but they all must be in working order. No cells could live long without their jobs being done. Ribosomes have been called construction sites and factories; they make the proteins that cells utilize in almost all their structures and the enzymes that operate ubiquitously throughout the cells and cell systems catalyzing the chemical works of life. Hemoglobin is an example: it is a ribosome constructed protein utilized in blood cells to capture and carry oxygen throughout many cellular systems. Even the proteins in a ribosome are made by ribosomes, as well as the proteins in helicase and polymerase whose job it is to preserve and produce reliable blueprints and work orders for ribosomal operations.
Ribosomes are two piece machines that assemble around their blueprints of mRNA to do their work. Their parts are composed of ribosomal RNA (rRNA), and different proteins. Their structural rRNA and proteins vary from part to part: one of the parts with rRNA 1,500 nucleotides in length and 20 different proteins, and the other with rRNA some 100 and some 3,000 nucleotides long and 35 different proteins. Nucleotide sequence is as critical to RNA as amino sequence is to functional proteins. This machine requires 55 proteins and conservatively 10,000 nucleotides of rRNA. Chance construction is out of the equation, scientifically anyway. In a billion universes like our own and 100 billion years the chance probability is still zero. These kinds of arrangements do not happen by chance; this is engineering and design; it just happens to be way beyond our intelligence. It is instructing us. And that awes us.
Even the construction of ribosome, first in the cell nucleolus for framing and then out in the cytoplasm for finishing under what must be numerous controls, magnifies the order of complexity and presupposes the coevality (must exist at the same time together) of these structures. These DNA, RNA, protein systems are not reducible among their individual parts, products, and services. Therefore it seems reasonable to assume their simultaneous creation inside each of the first cells after their kinds and guaranteeing the perpetuity (existance over time, without change) of their kinds.
RNA Complexity (ribonucleic acid)
RNA is the coded transcription of the information in DNA that is meticulously co-produced by the DNA and protein enzyme catalysts in a highly orchestrated symphony of intertwined labor and control. Truly stunning, it is a wonder to behold.
RNA is not just a copy of DNA with a slightly different sugar molecule, one stranded not two, and using uracil (U) instead of thymine (T) to bind to adenine (A); it is that, but it is more. The mRNA strands are the transcribed blue prints sent out into the cytoplasm to be translated by the ribosome. The tRNA strands are individualized amino acid carriers that match up along the mRNA strand and co-catalyze the peptide bonded amino acid chains of protein construction. And, in a structural capacity, all ribonucleic protein (RNP) structures have their own RNA elements and parts; rRNA in ribosome and vRNA in vaults are examples.
The code complexities are the same, but RNA is more of a worker and tool of the code than the repository of it. mRNA carries the intelligence out of the nucleus and into the cytoplasm where it is read and acted upon. tRNA is the labor force that coordinates and transports all the construction materials and facilitates their joining at the ribosome construction sites. Robert Holly (1962) solved the structure of tRNA, which looks a bit like a Celtic cross attaching its specific amino acid at its top and having at its base the nucleotide word that pairs with mRNA at a specific site on the ribosome. Lastly, the various possible roles of the RNA in RNP structures are driving much current research.
Every thing we learn adds to a complexity that simply can not be reduced without serious damage to the organism. Indeed damage from toxins and mutations are some of the most heuristic objects and generators of this research, as is cancer and other diseases, all adding to our understanding of how these complex machines work, communicate, and network.
Helicase Complexity
Spinning DNA as fast as a jet engine where it climbs along the double helix, unzipping it at its nose and re-zipping it at its tail, helicase catalyzes the construction of mRNA, copying the code as it passes along. Gathering free RNA nucleotides through a special induction tunnel, it matches them, and then shunts the forming mRNA strand out its side. It must start and stop at precise locations controlled by many factors releasing its products and reassembling somewhere else to do another job. Therefore, helicase is not only a precise and complicated catalyst, but it must be responsive to various work controls; there is more intelligence in this than we know of, and this is a growing field of molecular experimental research.
Helicase is not a random grouping of proteins, nor are the proteins that compose it a random grouping of amino acids. Again, this is a precision machine far outside the realm of mathematical random probability. Added to its own complexity, the fact that its own blue prints are some of the products it makes as it slides precisely along the complex DNA molecule, the complexity becomes irreducible, incapable of simplifying without destroying the whole purpose of the system. The number of sequential dependent operations in this system, its fabrication, maintenance, and reproduction, begins to look like the grains of sand upon the sea shores.
Polymerase Complexity
These catalytic machines reproduce DNA reading it, checking it, and repairing it as they go about their precision jobs. Along with helicase, it must unwind and unzip the DNA stand and then produce two duplicate strands from the two halves. This too is a wonder to behold.
As the DNA is split down the middle along the base pairs, one half of the split strand is reproduced directly by polymerase factors pairing DNA nucleotides. But the other half is winnowed out in a loop to be reproduced backwards and then joined to the completed previous loop. There is a quality control aspect to this procedure as helicase factors check its accuracy pairing across the products, and if there is an error, progress down the DNA strand is halted while the defective strand or loop is severed and rebuilt. This ballet has the relevant factors embracing pulling apart, re gathering, spinning off, swinging out drawing back, and combined producing two identical DNA strands. The movement of these factors and the distances they must operate over are magnificent, like a molecular loom of ingenious innovation and design.
Again the number of proteins and their number of amino acids, the sequences of their construction and precise folded forms are all essential to their flexibilities and active sites. Mistakes, reductions, or additions are together counterproductive. The continuance of life and the perpetuity of the organism are dependent on the proper networking of every factor. Per-organism, it is just not reducible.
There are polymerases used in amplifying human DNA that come from organisms that normally live in extremely heated environments. These lack some of the code checking complexity of human polymerase, but then they uniquely are able to survive the sequential heating that is required by the amplifying procedures which human polymerase cannot. It is assumed that the high temperature of its native habitat provides that essential check on its accuracy. Not withstanding, this is not an argument for a reduction in complication, rather it argues for specie specific design variations. Their individual complexities remain irreducible.
CONCLUSIONS
The amazing order, inter working, and networking among the DNA/RNA/protein systems express a wisdom that is nothing less than an observation of the eternal power and divine nature of the Creator. It takes a lot of effort not to see this. It seems as though one could see the actual design orders marshaled out to implement the divine decree for living things to multiply and fill the earth after their kinds. Insuring their individual integrity within their kinds, this is the most stable information storage system known to man. Receiving the cell principal as confirmed by all evidences, therefore, the naïve notions speculated by the doctrine of evolution ought to be relegated to the history of science, and not to be presented as current science. Much less should it be mandatory for those who would do science to kiss the ring of Darwin in order to enter though her portals. Ridged, officious, and dogmatically bigoted presumptions ought not to be the bench mark of scientific inquiry, right? Then let not the shibboleth of infinite time and chance exclude any longer those who would discover and learn, or those who would teach, for that matter.
References:
1. Biology God’s Living Creation: Keith Graham, Laurel Hicks, Delores Shimmim, and George Thompson; A Beka Book Publications, (1986)
2. www.ncc.gmu.edu/dna/base.htm[/url]
3. www.dnai.org/a/index.html]Finding the DNA Structure, Copying, Reading, & Controlling DNA Code[/url]
4. www.dnai.org/a/index.html]Finding the DNA Structure, Copying, Reading, & Controlling DNA Code[/url]
I wrote this back in 2006 as an apologetic to my secular teacher friends, who questioned my creationist approach to biology xDICEx
The Cell Principal from the time of Robert Hooke (1665), Mathias Schleiden (1838), and Theodore Schwann (1839) until now in biology has been: First, "That all living things are made up of living units called cells and cell products," and Second, "That all cells come from pre-existing cells." 1. That this fundamental principal of biology is apparently contradicted in the fundamental principal of evolution (i.e. that cells evolved by random chance out of decomposition and solution of inorganic elements in the primordial sea.) is not widely admitted by current literature in education or the sciences. The notion that simple cells could evolve in some primordial environment, and that given great amounts of time, could also change into more complex forms, forms to which the cell principal might then apply to, seems to be the dogma of the day.
That notion, perhaps, was credible between 1860 and the early 1900's but, since the 1950's, with the advances in molecular biology, it seems obviously outdated and unduly ridged. As microscopy advanced with resolutions down into the angstrom scale and techniques that cryogenically paused molecular operations in process, the observational field in biology made a quantum leap. While those techniques combined with the DNA structural breakthroughs of Watson and Crick in 1953, molecular research and cytology was discovering a greater complexity than ever before imagined. There is no such thing as a simple cell. In fact this paper addresses a rather tiny portion of that complexity, perhaps a 10 billionth part, if that, and yet, this little part's complexity, as complexly as we now know it, is far beyond our collective scientific scope. Though we have much systematic, descriptive and analytic elaboration, there are more questions and mysteries than ever before. The ounces we have come to know provoke tons of research into that which we have come to question.
What do we know? The simplest statement of the DNA/RNA/Protein inter complexity is: Precision DNA polymers and precision molecular protein machines make RNA strands, and these precision strands working together with other precision protein machines make protein and protein machines. Copying DNA is incredibly complex, and yet it has to be done to perpetuate life. The instructions for making the protein machines are encoded in the DNA, which code is useless without the machines; of course the machines cannot be made without the instructions in the DNA. The precise sequential encoding and sequential protein construction involved in this process is in the order of tens of thousands, if not millions. The most obvious inference in this chicken and egg scenario is the confirmation of the Cell Principal, and an equal rejection of the Evolution Principal. Only a living cell and cell products can do the work and make the things of living cells: all RNA has come from pre-existing DNA and all Protein machines from pre-existing machines. The first cells had it all, because it's obviously all or nothing. And the random probability of systems ordered this complexly is virtually zero. This is the current scientific evidence, and it is evidence of design and intelligent construction and confirms the thesis that these organisms must have been made complete from the start, and moreover, each according to its kind.
Helicase and polymerase are two of the complex machines involved in replicating DNA and transcribing DNA into RNA. Next to these are the ribosomes, bi-structural protein complexes that read the messenger RNA (mRNA) strands and construct the encoded protein structures out of their individual amino acid parts gathered up by their individual transfer RNA (tRNA) carriers. The ribosomes thus translate the coded information into sequentially peptide bonded amino acids making complexly folded proteins. Ribosomal structures, as well as Helicase and polymerase structures, are encoded in DNA, and that is how they have come into being since the creation. But, quite obviously, the first of their kinds were created complete from the start; at least that is what the evidence indicates. The first cells must have had it all.
DNA Complexity (deoxyribonucleic acid)
DNA is a double helical polymer composed of deoxyribos sugar, phosphate, and the four nucleic bases adenine, thymine, cytosine, and guanine.2 The sugar/phosphate iterations form the two strands along both sides, and joining the opposed sides like runs on a ladder are two paired base molecules. Each sugar/phosphate side member having one of the bases bonded to the sugar group toward the side of the polymer and bonded toward the middle to its paired base counterpart, (adenine A to thymine T, cytosine C to guanine G: A/T or T/A and C/G or G/C.) The overall acidic properties of the polymer are attributable to the phosphate groups along its two sides. The fundamental element in this spiraling helix is the nucleotide which is one sugar/phosphate group with its unpaired base attached. A 16 inch strand is nearly 500 million times longer than its 2 nanometer width and may have more than 200 million nucleotide pairs. Human DNA in 46 chromosomes has about 3,165 million base pairs.
When this ladder is split down the middle separating the paired bases, two strands are expressed that constitute a 4X code at each nucleotide: A, T, C, or G, every three nucleotides of which representing a coded word of 64X possibilities. With some duplication the 20 bio-amino acids are represented with their own words along with some control words that encode operations essential to the replication, transcription, and translation devices that utilize this code for highly specific work. These 64 words have been experimentally demonstrated, with their individual amino acids and operations identified.3. But whether this is the sole extent of the sequences, or rather the only level of meaning is a question. Transfer RNA, (tRNA), having from 60 to 95 nucleotides which also must be transcribed off sequential DNA locations, has at least 20 different multi-word expressions; what else? What about the many ribonucleic protein structures, (RNP), e.g. Vaults and Ribosomes? Where are their structural RNA parts encoded? Lastly there are many external factors and controls that operate on DNA sites suitable to their influence: some are known; how many are not? Moreover, as DNA twists like licorice two groves are expressed where the active sites on the paired bases are presented in the major and minor groves. How many cell processes and cellular machines might utilize this structured information?
The packaging of DNA to fit into and be useful within the nucleus of cells is another wonder. First the twisting of the strand reduces its absolute length, but coiling twice around 8 histone proteins at precise points all along its length forms an 11 nanometer “string of pearls,” called a nucleosome string. This string is again coiled and, by the 9th histone protein, bound in solenoids of twisting groups of 6 to 8 nucleosome forming the 30 nanometer fibers called chromatin.4
The inter working of histone and DNA increases the complexity significantly in all other operations DNA is involved in. All operative factors network with these packaging states and coordinate their functions. Under meiosis and mitosis the DNA is coiled and folded more, but these above are normal DNA states during interphase where most cellular life work is done.
In any living organism all of its complexity from beginning to end is encoded in its DNA. And all that information is useless without the rest of that cell or cells. It has been said, that if the information in a teaspoon full of DNA were written into paperback books, the stack would reach from the earth to the moon and back 400 times. That is a lot of complexity in a very little package, but without a ribosome it is gibberish, useless.
Ribosomal Complexity
It takes a great deal of nonscientific, dogmatic inflexibility to believe that something as complex as a ribosome and yet as essential to all cellular life, could come into being on its own. The parts of this machine must not only all be there for it to do its job, but they all must be in working order. No cells could live long without their jobs being done. Ribosomes have been called construction sites and factories; they make the proteins that cells utilize in almost all their structures and the enzymes that operate ubiquitously throughout the cells and cell systems catalyzing the chemical works of life. Hemoglobin is an example: it is a ribosome constructed protein utilized in blood cells to capture and carry oxygen throughout many cellular systems. Even the proteins in a ribosome are made by ribosomes, as well as the proteins in helicase and polymerase whose job it is to preserve and produce reliable blueprints and work orders for ribosomal operations.
Ribosomes are two piece machines that assemble around their blueprints of mRNA to do their work. Their parts are composed of ribosomal RNA (rRNA), and different proteins. Their structural rRNA and proteins vary from part to part: one of the parts with rRNA 1,500 nucleotides in length and 20 different proteins, and the other with rRNA some 100 and some 3,000 nucleotides long and 35 different proteins. Nucleotide sequence is as critical to RNA as amino sequence is to functional proteins. This machine requires 55 proteins and conservatively 10,000 nucleotides of rRNA. Chance construction is out of the equation, scientifically anyway. In a billion universes like our own and 100 billion years the chance probability is still zero. These kinds of arrangements do not happen by chance; this is engineering and design; it just happens to be way beyond our intelligence. It is instructing us. And that awes us.
Even the construction of ribosome, first in the cell nucleolus for framing and then out in the cytoplasm for finishing under what must be numerous controls, magnifies the order of complexity and presupposes the coevality (must exist at the same time together) of these structures. These DNA, RNA, protein systems are not reducible among their individual parts, products, and services. Therefore it seems reasonable to assume their simultaneous creation inside each of the first cells after their kinds and guaranteeing the perpetuity (existance over time, without change) of their kinds.
RNA Complexity (ribonucleic acid)
RNA is the coded transcription of the information in DNA that is meticulously co-produced by the DNA and protein enzyme catalysts in a highly orchestrated symphony of intertwined labor and control. Truly stunning, it is a wonder to behold.
RNA is not just a copy of DNA with a slightly different sugar molecule, one stranded not two, and using uracil (U) instead of thymine (T) to bind to adenine (A); it is that, but it is more. The mRNA strands are the transcribed blue prints sent out into the cytoplasm to be translated by the ribosome. The tRNA strands are individualized amino acid carriers that match up along the mRNA strand and co-catalyze the peptide bonded amino acid chains of protein construction. And, in a structural capacity, all ribonucleic protein (RNP) structures have their own RNA elements and parts; rRNA in ribosome and vRNA in vaults are examples.
The code complexities are the same, but RNA is more of a worker and tool of the code than the repository of it. mRNA carries the intelligence out of the nucleus and into the cytoplasm where it is read and acted upon. tRNA is the labor force that coordinates and transports all the construction materials and facilitates their joining at the ribosome construction sites. Robert Holly (1962) solved the structure of tRNA, which looks a bit like a Celtic cross attaching its specific amino acid at its top and having at its base the nucleotide word that pairs with mRNA at a specific site on the ribosome. Lastly, the various possible roles of the RNA in RNP structures are driving much current research.
Every thing we learn adds to a complexity that simply can not be reduced without serious damage to the organism. Indeed damage from toxins and mutations are some of the most heuristic objects and generators of this research, as is cancer and other diseases, all adding to our understanding of how these complex machines work, communicate, and network.
Helicase Complexity
Spinning DNA as fast as a jet engine where it climbs along the double helix, unzipping it at its nose and re-zipping it at its tail, helicase catalyzes the construction of mRNA, copying the code as it passes along. Gathering free RNA nucleotides through a special induction tunnel, it matches them, and then shunts the forming mRNA strand out its side. It must start and stop at precise locations controlled by many factors releasing its products and reassembling somewhere else to do another job. Therefore, helicase is not only a precise and complicated catalyst, but it must be responsive to various work controls; there is more intelligence in this than we know of, and this is a growing field of molecular experimental research.
Helicase is not a random grouping of proteins, nor are the proteins that compose it a random grouping of amino acids. Again, this is a precision machine far outside the realm of mathematical random probability. Added to its own complexity, the fact that its own blue prints are some of the products it makes as it slides precisely along the complex DNA molecule, the complexity becomes irreducible, incapable of simplifying without destroying the whole purpose of the system. The number of sequential dependent operations in this system, its fabrication, maintenance, and reproduction, begins to look like the grains of sand upon the sea shores.
Polymerase Complexity
These catalytic machines reproduce DNA reading it, checking it, and repairing it as they go about their precision jobs. Along with helicase, it must unwind and unzip the DNA stand and then produce two duplicate strands from the two halves. This too is a wonder to behold.
As the DNA is split down the middle along the base pairs, one half of the split strand is reproduced directly by polymerase factors pairing DNA nucleotides. But the other half is winnowed out in a loop to be reproduced backwards and then joined to the completed previous loop. There is a quality control aspect to this procedure as helicase factors check its accuracy pairing across the products, and if there is an error, progress down the DNA strand is halted while the defective strand or loop is severed and rebuilt. This ballet has the relevant factors embracing pulling apart, re gathering, spinning off, swinging out drawing back, and combined producing two identical DNA strands. The movement of these factors and the distances they must operate over are magnificent, like a molecular loom of ingenious innovation and design.
Again the number of proteins and their number of amino acids, the sequences of their construction and precise folded forms are all essential to their flexibilities and active sites. Mistakes, reductions, or additions are together counterproductive. The continuance of life and the perpetuity of the organism are dependent on the proper networking of every factor. Per-organism, it is just not reducible.
There are polymerases used in amplifying human DNA that come from organisms that normally live in extremely heated environments. These lack some of the code checking complexity of human polymerase, but then they uniquely are able to survive the sequential heating that is required by the amplifying procedures which human polymerase cannot. It is assumed that the high temperature of its native habitat provides that essential check on its accuracy. Not withstanding, this is not an argument for a reduction in complication, rather it argues for specie specific design variations. Their individual complexities remain irreducible.
CONCLUSIONS
The amazing order, inter working, and networking among the DNA/RNA/protein systems express a wisdom that is nothing less than an observation of the eternal power and divine nature of the Creator. It takes a lot of effort not to see this. It seems as though one could see the actual design orders marshaled out to implement the divine decree for living things to multiply and fill the earth after their kinds. Insuring their individual integrity within their kinds, this is the most stable information storage system known to man. Receiving the cell principal as confirmed by all evidences, therefore, the naïve notions speculated by the doctrine of evolution ought to be relegated to the history of science, and not to be presented as current science. Much less should it be mandatory for those who would do science to kiss the ring of Darwin in order to enter though her portals. Ridged, officious, and dogmatically bigoted presumptions ought not to be the bench mark of scientific inquiry, right? Then let not the shibboleth of infinite time and chance exclude any longer those who would discover and learn, or those who would teach, for that matter.
References:
1. Biology God’s Living Creation: Keith Graham, Laurel Hicks, Delores Shimmim, and George Thompson; A Beka Book Publications, (1986)
2. www.ncc.gmu.edu/dna/base.htm[/url]
3. www.dnai.org/a/index.html]Finding the DNA Structure, Copying, Reading, & Controlling DNA Code[/url]
4. www.dnai.org/a/index.html]Finding the DNA Structure, Copying, Reading, & Controlling DNA Code[/url]
I wrote this back in 2006 as an apologetic to my secular teacher friends, who questioned my creationist approach to biology xDICEx
