Evolution from Space by Fred Hoyle and Chandra Wickramasinghe is a revolutionary book concerning the interpretation of the biological, astronomical, and mathematical evidence which indicates that evolution of life occurs on a galactic scale. The authors’ arguments against important assumptions of natural selection and the origin of life are still applicable and their proposed solution seems reasonable, although perhaps subject to improvements, especially if one makes no a priori assumptions that life originated on Earth. Besides, the chondrites provide clear support for their theory and I believe trivially contradict the spontaneous generation on Earth hypothesis.
This lecture provides a decent glance at Fred Hoyle’s understanding of the universe. One can certainly say that he held a view quite different than most.
Fred Hoyle’s IFS Lecture December 1982
… the non-coding sequences have certain statistical features in common with natural and artificial languages. Specifically, we adapt to DNA the Zipf approach to analyzing linguistic texts. These statistical properties of non-coding sequences support the possibility that non-coding regions of DNA may carry biological information.
With that quote in mind, consider that Francis Crick suggested in 1975 that life on Earth could have been the result of “Directed Panspermia.”
Also, check out Cosmic Serpent: DNA and the Origins of Knowledge for Jeremy Narby’s thoughts on this subject.
Messages in DNA? Directed Panspermia? Great ideas for a science fiction movie, yes! But unless scientists find evidence that life definitely arose on Earth through natural processes, then these ideas can and should be considered legitimate hypotheses — they both can be refuted by evidence showing that they are false.
Let’s entertain the rather wild possibility that the information contained in these non-coding regions may in fact be information encoded in the DNA by an advanced “thing” which purposely sent life to Earth. This would suggest the question: “At what level of development did cells and bacteria arrive on Earth?” Fully developed with DNA, ribosomes, and protein synthesis? Or, perhaps just DNA contained in a capsule?
If an advanced intelligence wanted to send a message to be received by an organism which eventually developed enough ability to discover this message, how would it do this? What would the message be? What would be the context of the message?
Would it be possible to encode a message as “form” in matter. By form, I mean something like studying the processes and relationships of molecular biology, for instance see: The Molecular Basis of Life. The incredible form of the DNA transcription; the fascinating ability of the kinesin protein to travel microtubules; could these forms and relationships be the message? If the context is biological travel in space, might these cellular forms and relationships be teaching us how to expand and develop in space?
But a message based on form seems to be invalid because it is the non-coding regions of DNA which are not expressed in protein structures that contain the statistical properties of Zipf. However, I think we still have much to learn about DNA and its interactions with the rest of the cell which may change the way we view DNA. It just seems hard for me to understand how 1,000,000 specially crafted objects (proteins) of various shapes thrown in a zero gravity room together could somehow bounce and collide to eventually create an organized dynamic transport mechanism across that same room — not to mention the dozens of other cellular processes. So, where does the form of cellular processes arise?
These thoughts came as I was watching 3D animations of kinesin protein travel along microtubules. Perhaps we could design a sort of kinesin vehicle which would travel along a microtubule connection from the Earth to Moon? Or, they could serve as connections between asteroid space bases suspended in the Lagrangian points. No need for rocket fuel, it would be similar to magnetic trains. What would it imply if an idea for space travel and transport could be found inside the cell?