I will praise thee; for I am fearfully and wonderfully made:... Psalm 139:14
"A molecular machine, according to an article in the journal Accounts of Chemical Research, is “an assemblage of parts that transmit forces, motion, or energy from one to another in a predetermined manner.”
Behe then posed the question, “Can all of life be fit into Darwin’s
theory of evolution?,” and answered: “The complexity of life’s
foundation has paralyzed science’s attempt to account for it; molecular
machines raise an as-yet impenetrable barrier to Darwinism’s universal
reach.”
Selected List of Molecular Machines
1. Bacterial Flagellum
The flagellum is a rotary motor in bacteria that drives a propeller
to spin, much like an outboard motor, powered by ion flow to drive
rotary motion. Capable of spinning up to 100,000 rpm one paper in 
Trends in Microbiology
called the flagellum “an exquisitely engineered chemi-osmotic
nanomachine; nature’s most powerful rotary motor, harnessing a
transmembrane ion-motive force to drive a filamentous propeller.” Due to its motor-like structure and internal parts, one molecular biologist wrote in the journal Cell, “more so than other motors, the flagellum resembles a machine designed by a human.” Genetic knockout experiments have shown that the E. coli flagellum is irreducibly complex with respect to its approximately 35 genes.
2. Eukaryotic Cilium
The cilium is a hair-like, or whip-like structure that is built upon a
system of microtubules, typically with nine outer microtubule pairs and
two inner microtubules. The microtubules are connected with nexin arms
and a paddling-like motion is instigated with dynein motors. These machines perform many functions in Eukaryotes, such as allowing
sperm to swim or removing foreign particles from the throat. Michael
Behe observes that the “paddling” function of the cilium will fail if it
is missing any microtubules, connecting arms, or lacks sufficient
dynein motors, making it irreducibly complex.
3. Aminoacyl-tRNA Synthetases (aaRS)
aaRS enzymes are responsible for charging tRNAs with the proper amino
acid so they can accurately participate in the process of translation.
In this function, aaRSs are an “aminoacylation 
machine.” Most cells require twenty different aaRS enzymes, one for each amino
acid, without which the transcription/translation machinery could not
function properly. As one article in Cell Biology International
stated: “The nucleotide sequence is also meaningless without a
conceptual translative scheme and physical ‘hardware’ capabilities.
Ribosomes, tRNAs, aminoacyl tRNA synthetases, and amino acids are all
hardware components of the Shannon message ‘receiver’. But the
instructions for this machinery is itself coded in DNA and executed by
protein ‘workers’ produced by that machinery. Without the machinery and
protein workers, the message cannot be received and understood. And
without genetic instruction, the machinery cannot be assembled.” Arguably, these components form an irreducibly complex system.
4. Blood clotting cascade
5. Ribosome
The ribosome is an “RNA machine” that “involves more than 300
proteins and RNAs”
to form a complex where messenger RNA is translated into protein,
thereby playing a crucial role in protein synthesis in the cell. Craig
Venter, a leader in genomics and the Human Genome Project, has called
the ribosome “an incredibly beautiful complex entity” which requires a
“minimum for the ribosome about 53 proteins and 3 polynucleotides,”
leading some evolutionist biologists to fear that it may be irreducibly
complex.
6. Antibodies and the Adaptive Immune System
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