P-T-C adaptation and extinction: the case of the lizards.

May 14th, 2010

As a young scientist in the 1950′s I was introduced to thermodynamics by Turner and Verhoogen’s book [Igneous and Metamorphic Petrology1] which was the basis a course given at Sheffield University, England. I was intrigued by Bowen’s Reaction Series which related minerals to pressure-temperature and chemical environment, and how so many things in nature seemed to depend on one or more of these three variables.

At the same time I was deeply involved in palaeontology, palaeo-geography, human zoology and mathematics. As a student stratigrapher it was apparent that climate and the atmosphere were major controls on evolution. A course in mathematical climatology offered in the Geography Department integrated many of the ideas of thermodynamics into weather prediction and early forms of climate modelling – ideas that I was able to utilise in an expanding view of palaeo-geography as it extended through time as historical geology. These were all things that were bombarding my mind during my undergraduate years at Sheffield and it was not until later as I began reacting with P. C. Sylvester-Bradley on questions of the concept of a species and evolutionary theory that I understood the real importance of P-T-C in the history of life. Climate and the atmosphere played an immense role in the the development of Earth and it’s living systems: from the setting of the vast latitudinally controlled coniferous forests to the adaptation of the Tibetans to life in the Himalayas.

Articles like that of Dr. Barry Sinervo, professor of ecology and evolutionary biology at the University of California, Santa Cruz, on the widespread extinction of lizard populations as a result of climatic change are part of the continuous documentation of the importance of P-T-C on Earth’s development [Science, May 14th, 2010]. Accumulating an extensive database Dr. Sinervo’s group was able to document that extinction amongst lizard’s was due not to habitat loss but to climate warming [since 1975] that is driven by increased atmospheric CO2. The essential factor is well known to those who study the rattle-snake in that rattle-snakes use heat to warm up their body temperature but cannot stay in the heat too long – it will kill them. Rattle-snakes, once sufficiently warmed, move into the shade. It is the same with other amphibians and Dr. Sinervo notes that with lizards, once they retreat into the shade there is less food to hunt. The implication is that heat pushes the lizards into a cooling location and they die of starvation! “These lizards need to bask in the sun to warm up, but if it gets too hot they have to retreat into the shade, and then they can’t hunt for food. At the extinct sites in the Yucatan, we found that the hours per day they could be out foraging had collapsed. They would barely have been able to emerge to bask before having to retreat……We thought we’d see evolution occurring in response to climate change, but instead we’re seeing extinctions. Beyond a certain point, the lizards can’t adapt.

Science is definite in that factors other than temperature, pressure and chemical environment, come into play in the evolutionary process: catastrophic habitat loss for example. However, more and more research is showing the classical controls on adaptation, especially temperature and chemical environment, are major driving forces effecting Earth’s biocoenoses today AND these forces are a direct result of humankind’s activity.

1Igneous and Metamorphic Petrology,694 p., McGraw Hill, New York, 1951.

………………………………………………………………………………………………Comment by Professor George F. Hart, May 14th, 2010.

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The Utility of the hierarchical classification of Homo

December 14th, 2009

I believe I have a record that can prove I am not a racist but I do take issue with many geneticists who claim that race is irrelevant because we all differ from one another by a minute amount of our DNA. For example, Richard Hayer of the Center for Genetics and Society said “modern science reveals that genetic differences are trivial and that ‘race’ is an almost meaningless descriptor”. Whereas he was correct in his first statement he is decidedly wrong in his second. The notion of separate interbreeding populations forming distinct ethno-cultural gamodemes is a very valid concept for understanding Protosociety. As a social concept to understand Protosociety, the spatial distribution of human variation is clearly significant, despite the ideologues of the west coast of the USA who rightly see genetic variation within the global population as continuous – missing the point that Cultures are separated on their differences not their similarities and that physically each geographic area did show a unison of characteristics that led earlier anthropologists to define human variants. These variants were not significant, and probably did not exist during Archaeosociety and are breaking down since Eusociety commenced. However, during Protosociety they developed and were important concepts influencing people and even today accepting such differences can have decidedly important benefits to health and education and the general well-being of all of humankind.

The problem seems to me to be related to the modern education of bio-scientists.: one flaw is that they do not seem to understand TAXONOMY. The older generation had a strong background in both taxonomic theory and practice, and understood that taxa are separated primarily by differences not similarities. A useful taxonomy of humankind does use a variant-based hierarchy; and the resultant classification is based upon a unison of measurable and visible physical traits. To deny this is bowing down to political correctness: to use it as the basis for racism is both unethical and evil. It is for this reason that I continue to use the geographically based, physical gamodeme classification. for humankind. As I have said elsewhere:

“The combination of various geographical effects was evident in the isolation of the cultural gamodemes that formed the traditional interbreeding populations of Homo sapiens by the end of the Pleistocene Epoch [11,500 years ago]. By this time the archaeosociety of the hunter-gatherer was being replaced regionally by protosociety as agriculture developed”, Hart, 2008, p73.

THE CLASSICAL CLASSIFICATION OF HOMO SAPIENS

Homo sapiens var africanensis and the African Cultures.

Homo sapiens var caucasensis and the European Cultures.

Homo sapiens var mongolensis and the Asian Cultures.

Homo sapiens var australensis and the Australasian Cultures.

Homo sapiens var Khoisanensis and the Southern African Cultures.

An interesting observation by Geoffrey Miller in the Economist: “The World In 2010” is that “The looming crisis in human genetics” is precisely the problem that genetic studies are showing how we are all a product of out physical gamodeme.  I believe this is something we should embrace, for the good of humanity, not shun as incorrect.

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68 fundamental molecules for cellular life suggested.

September 8th, 2008

San Diego School of Medicine scientist Professor Jamey Marth suggests the basic components of the cell [Nucleic Acids, Proteins, Lipids and Glycans] are based upon essentially 68 molecules To the commonly accepted 8 nucleosides of nucleic acids and the 20 amino-acids are added 8 lipid and 32 glycan molecules.  To the Genome and the Proteome we can add the Glycome and Lipidome if we are to obtain a more complete accounting of the cellular processes that control the origin and development of living systems.

Professor Jamey D. Marth, 2008, A unified vision of the building blocks of life. Nature Cell Biology, Vol 10(9):1015.

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Gene Classification

November 12th, 2008

The feature article in November-December 2008, New Scientist alerts us to what many have suspected for a long time.  Genomic Confounds Gene Classification” by Seringhaus and Gerstein points to large scale genomic studies that question the prevailing hypothesis in molecular biology that genes are distinct parts of the DNA molecule that operate by producing an mRNA transcript which translates into a polypeptide that folds to form a protein that has a specific function within the organism.  This one gene – one protein view is at the core of our current understanding of biological processes.  Nevertheless, scientists have suspected that whereas the idea is fundamental it is too simplistic.  As I noted in “Evolution and the Future of Humanity” [Hart, 2008]

 

“Those parts of the DNA molecule that do code directly for proteins are termed exons, and those parts which do not are called introns. The intron regions of the chromosome molecule are often referred to as junk sequences. These sequences are probably important in controlling the development of traits in some way or another because chromosome duplication processes are far too precise to allow replication of useless materials.

 

Seringhaus and Gerstein note that as “high-throughput genomics is generating data on thousands of gene products ….. biology’s basic unit, it is clear, is not nearly so uniform nor as discrete as once thought”.  Although the basic concept of one gene – one protein still stands there is a need for an enhanced taxonomy of genes that can improve our ability to classify and interpret the molecular products of the DNA – RNA genomes. Current analytical methods that simultaneously examine the relationship of millions of bases along the genome are showing that “creating an RNA transcript from a DNA region is more complex”, involving transcription of areas of the genome  beyond the known boundaries of a specific gene often involving areas of the genome thought to be relic genes harbored in the introns. These introns were previously thought to be spliced out prior to protein production in the Eukaryotes.  It is now seen that introns can be incorporated in the protein during transcription and exons can be discarded – this complicates the work of the systematicist and demands a new taxonomy to allow a more rigorous and comprehensive classification system.

 

The authors significantly note “understanding of gene regulation is also changing”. The classical idea that the repressors, operators and promoters are located in close proximity to one another, as exemplified by the classic lac operand in bacteria is again too simplistic: “in mammalian systems and other higher eukaryotes … genes can be regulated very far upstream by enhancers over 50,000 base pairs away, even beyond adjacent genes”.  This is done by the folding ability of DNA.  Moreover, we have known for a while that gene activity can be modulated by epigenetic effects such as the addition of methyl groups.

Genomics is at a developmental stage that many other natural sciences passed through.  My own early interests were in taxonomy and classification of microfossils and in that field it was recognized, early on, that only with a rigorously enforced and standardized nomenclature integrated into a well thought out taxonomic framework could progress ensue. Seringhaus and Gerstein imply this is what is needed for gene classification if genomics is to progress. In Neontology and Palaeontology nomenclature is standardized through International Codes e.g. The International Code of Botanical Nomenclature and the authors point out the need for such a code for genes. Nomenclatural standardization is necessary as a means of unambiguous communication but also an added value is that a standardized naming system when viewed within a classification is also a global knowledge holder about each object classified.  The classification structure itself becomes a a knowledge web that can be queried as a massive bio-database.  Seringhaus and Gerstein use the semantic web of the internet and the ability of Google to extract information, as an example of a rich classification scheme.  However, I would urge caution of any direct approach in this direction because the web as illuminated by Google will produce a classification in which systematic anarchy prevails. Only with a rigorously enforced and standardized nomenclature within a well thought out [multiple] taxonomic framework would a semantic web produce what is needed.  Anyone who uses the web for non-trivial scientific research  is aware that the opinion of a single professional is worth more than those of a thousand amateurs [anyone know who said that first?]. 

 

It is important to remember the following distinctions: “Taxonomy pertains to a system devised for dividing up things into different types and how they are arranged one to another.  Classification pertains to an actual classification that is set up for a group of things.  Systematics is the actual classification of individual things within a taxonomic framework.” Hart, 1996.  In palaeontology the route to a more stable palaeo-species classification was based in the simple move from a morphospecies definition involving measurable traits to one in which evolutionary [temporal] acquisition of traits is important. This led to a significant advance in the inherent knowledge content of fossil classifications. 

 

Now that we realize that the DNA sequence in a single region does not necessarily define a gene we can incorporate the biochemical effect, [developed by transcription] on the functional phenotype, into gene classification.  Moreover, the external and internal selection pressures operating during transcription need to be more fully understood and incorporated into.  Clearly, the phenotypic effect does not necessarily capture the function of the gene at the molecular level and to understand the genotype we need to know how biochemical products affect the metabolic pathways and the resulting biological system.  All of these aspects need to be incorporated into an improved gene classification.

 

The taxonomy for genes needs to be non-hierarchical i.e. a multi-level taxonomy. The authors hint at a classification based on gene ontology that uses directed acyclic graph structure [DAG] within which a multiple classification exists but all pointing towards a single gene.  What is interesting in the DAG approach is that the multiple classifications [each for its own purpose] and each of which points to a single object i.e. a gene, allows a web to be built that can be interpreted in semantic terms.  It is a system that would lend itself to an AI approach to gene systematics.  Recently, I have been looking at the SOAR programming language as a system for understanding complex relationships, like those within a genome, or a cultural gamodeme, and perhaps this is the direction in which to develop a useful classification of genes.  SOAR can allow a single gene to have multiple functions and multiple genes to have a single function within a semantic framework.  This area I hope to explore in the future [as soon as I learn how to use SOAR correctly!].  Such a system could result in a greater understanding of evolution and relationships among living systems.

 

 

References:

 

Hart G. F. 1996  http://www.geol.lsu.edu/hart/NOTES/taxonomy.htm

Hart G. F. 2008  Evolution and the Future of Humanity:  Homo sapiens’ galactic future. SCI& Publications, Boulder, Colorado. www.ScienceAnd.com

ISBN-13 978-0-9818642-0-4.

Seringhaus M. and Gerstein M. 2008 Genomics Confounds Gene Classification.  American Scientist, 96[6]:466-473.

 

George F. Hart.

Monday, November 10th , 2008.

 

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Cognitive expansion technologies

October 2nd, 2008

COGNITIVE EXPANSION TECHNOLOGIES

by W. S. BAINBRIDGE.

Journal of Evolution and Technology, 19[1]:8-16, 2008.
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Review by Professor George F. Hart, LSU.
Recommended reading.

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Professor Bainbridge’s theme is that the human mind is being transformed as individuals become more intertwined with electronic technologies that perceive, process and present information. This process will continue with advancements in W3 technologies that use human criteria and reasoning in their search methodologies: following the concept of W3 as an extended brain [memory + reasoning] that can be utilized by individuals. Professor Bainbridge, however, sees beyond this stage to one in which computers include personality traits of a user.

From my viewpoint, the excitement of this article is that Professor Bainbridge outlines one way whereby we may eventually be able to identify what I have called the ‘humanity trait(s)”; and, help to answer the question I posed “What of humanity do we want to incorporate into our robotic descendents?” [Hart, 2008]. The kind of development he envisages and documents is a ‘bottom up’ approach to training computers about the human mind. The cleverness of this lies in that such an approach is soundly grounded in the Theory of Evolution: the individuals within the cultural gamodeme will generate the important criteria that will dominate the system.

Professor Bainbridge outlines an approach that I find strikingly simple but with potentially profound consequences for the evolution of robotic intelligence. His unique approach is that the capture of an individual personality may be possible by one person answering many questions set by many other individuals. This could cause an intelligent computer to derive associations that provide a deeper insight into human reasoning: I wonder now if my own estimate of 300 years to develop a robot that has a manufactured consciousness and incorporates the ‘humanity trait(s)” is too long. Although I think Ray Kurzweil’s estimate is too short, perhaps this century will see Robotico earthensis (Hart, 2008) evolve.

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Hart, G. F., Evolution and the Future of Humanity, Homo sapiens’ galactic future. eBook edition. ScienceAnd Publications, Boulder, Colorado. ISBN-13 978-0-9818642-0-4 ,

Reference link: www.ScienceAnd.com.

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