meditations of aservantofJEHOVAH

Tuesday 20 December 2022

Be grateful for your body's flawless design.

A Physician’s Fantastic Voyage through Your Designed Body

On a new episode of ID the Future, Your Designed Body author and physician Howard Glicksman takes a close looks with Philosophy for the People podcast host Pat Flynn at Glicksman’s new book, co-authored with systems engineer Steve Laufmann. As Glicksman puts it, he and Laufmann consider not just how the human body appears but what it actually takes for it to work and not die, and what this implies for evolutionary theory.

Begin by piling up the layers of complexity in the human body — the layer upon layer of complex interdependent systems. Then ask hard questions about whether any blind and gradual evolutionary process could have kept our evolutionary ancestors alive at every generational stage as all this was gradually engineered by countless random mutations over millions of generations, beginning with the first single-celled organisms billions of years ago. Once one faces those hard questions without retreating to vague just-so stories about nature needing vision (or hearing or any number of other bodily functions) and therefore magically evolving it, at that point Darwinism’s story of gradual and blind evolution collapses. The explanation that is left standing, according to Glicksman, Laufmann, and Your Designed Body, is intelligent design. Download the podcast or listen to it here

Darwinism's failure as a predictive model XVIII

Darwinism's Predictions

Cornelius G Hunter

Ever since Darwin the universal evolutionary tree has been a unifying principle in biology. Evolution predicted that this universal tree can be derived by arranging the species according to their similarities and differences. And as more data became available, particularly from the dramatic breakthroughs in molecular biology in the latter half of the twentieth century, expectations were high for the determination of this tree. As one paper explains, “Once universal characters were available for all organisms, the Darwinian vision of a universal representation of all life and its evolutionary history suddenly became a realistic possibility. Increasing reference was made to this universal, molecule-based phylogeny as the ‘comprehensive’ tree of the “entire spectrum of life” (O’Malley and Koonin) But those expectations were dashed: “By the mid-1980s there was great optimism that molecular techniques would finally reveal the universal tree of life in all its glory. Ironically, the opposite happened.” (Lawton)

As one study explained, the problem is so confusing that results “can lead to high confidence in incorrect hypotheses.” And although evolutionists thought that more data would solve their problems, the opposite has occurred. With the ever increasing volumes of data, incongruence between trees “has become pervasive.” (Dávalos) As another researcher explained, “Phylogenetic incongruities can be seen everywhere in the universal tree, from its root to the major branchings within and among the various taxa to the makeup of the primary groupings themselves.” (Woese) These incongruities are not minor statistical variations and the general failure to converge on a single topology has some researchers calling for a relaxation from “tree-thinking.” (Bapteste, et. al.) Nor are these incongruities limited to protein-coding genes. As one research commented, “I’ve looked at thousands of microRNA genes, and I can’t find a single example that would support the traditional tree.” (Dolgin)

These incongruities have forced evolutionists to filter the data carefully in order to obtain evolutionary trees. As one paper explains, “selecting genes with strong phylogenetic signals and demonstrating the absence of significant incongruence are essential for accurately reconstructing ancient divergences.” (Salichos and Rokas) But this raises the question of whether the resulting tree is real: “Hierarchical structure can always be imposed on or extracted from such data sets by algorithms designed to do so, but at its base the universal TOL [tree of life] rests on an unproven assumption about pattern that, given what we know about process, is unlikely to be broadly true.” (Doolittle and Bapteste).

References

Bapteste E., et. al. 2005. “Do orthologous gene phylogenies really support tree-thinking?.” BMC Evolutionary Biology 5:33.

Dávalos L., et. al. 2012. “Understanding phylogenetic incongruence: lessons from phyllostomid bats.” Biological Reviews Cambridge Philosophical Society 87:991-1024.

Dolgin, E. 2012. “Phylogeny: Rewriting evolution.” Nature 486:460-462.

Doolittle, W., E. Bapteste. 2007. “Pattern pluralism and the Tree of Life hypothesis.” Proceedings of the National Academy of Sciences 104:2043-2049.

Lawton, G. 2009. “Why Darwin was wrong about the tree of life.” New Scientist January 21.

O’Malley, M., E. Koonin. 2011. “How stands the Tree of Life a century and a half after The Origin?.” Biology Direct 6:32.

Salichos L., A. Rokas. 2013. “Inferring ancient divergences requires genes with strong phylogenetic signals.” Nature 497:327-331.

Woese C. 1998. “The universal ancestor.” Proceedings of the National Academy of Sciences 95:6854-6859.

On the salt of the earth and the design Inference.

Salt of the Earth Regulates Habitability

David Coppedge

nasa’s astrobiology program leans heavily on the assumption that any location where liquid water can persist is a potential place for life to emerge and evolve. consequently, those interested in the question of life beyond the earth have typically limited their searches to watery places. usually those were planets orbiting within their particular “continuously habitable zone” (chz), defined as the distance from the host star where h2o could remain in the liquid state for long periods of time. the chz has inner and outer radii with temperatures between 0 and 100°c, the freezing and boiling points for h2o. if a planet stays within the chz throughout its orbit, it is deemed “habitable” whether or not it has inhabitants.

later astrobiologists realized that other locations with liquid water exist. subsurface oceans of water are suspected on icy moons like europa at jupiter, enceladus at saturn, triton at neptune, and possibly a few others. because in situ investigation of those places are unlikely till far in the future, we will restrict our discussion to the orbital chzs. one caveat about habitable zones is that they can migrate. some types of host stars become hotter or cooler over time. the chz, correspondingly, will move outward or inward.

Faint Young Sun

Our own sun is thought to have been 20 percent cooler in its early history. As Earth could not have migrated inward to adjust, this creates a “faint young sun paradox” that astrobiologists must address in their models of life’s history on Earth. If a faint sun resulted in Earth orbiting outside the CHZ for a time, it could have become a giant “Snowball Earth” that could only melt back to normal with difficulty. A Snowball Earth could be a dead end; the high albedo of water ice would reflect more solar warmth back out to space. Some doubt it could ever recover. It’s best, therefore, to avoid snowball scenarios in models of Earth history.

A deeper dive into requirements for habitability shows that it is too simplistic to assume that being “in the zone” (CHZ) qualifies a planet for habitability. The right atmosphere, crustal composition, inclination, obliquity, rotation period, and other factors bear strongly on the question. Books such as The Privileged Planet, Rare Earth, and A Fortunate Universe have added to the list of requirements, including factors like stellar class, the avoidance of tidal locking, and presence of a stabilizing large moon. Most recently, Denton’s The Miracle of Man and the earlier books in his Privileged Species series have focused attention on essential chemical elements for life — over a dozen of them — that must be available near the surface of putative habitable planets. His book The Wonder of Water (see the video below) explains H2O’s many properties that benefit life.

Climate Consequences

And yet one property of water — its ion content — has been largely neglected by astrobiologists. Table salt (NaCl) is the most common ionic compound in sea water. Its ease of dissolving in water sets up electrical properties between its positive sodium (Na+) and negative chlorine (Cl–) ions. As a paper discussed below says, “Salt affects seawater density and ocean dynamics via direct mass effects and through its influence on charge density and ionic interactions with polar water molecules.” One effect of salinity is lowering the freezing point of water; this is the reason for salting roads in winter.

Sea water on Earth presently contains about 35g/kg of NaCl. Has this value remained constant throughout the history of the Earth? And does the concentration of salt in a planet’s oceans have any effect on its habitability? Surprisingly, the relationship between salinity and habitability has received scant attention till now. News from Purdue University announced that “salt may be the key to life on Earth and beyond.”

The composition of the atmosphere, especially the abundance of greenhouse gases, influences Earth’s climate. Researchers at Purdue University, led by Stephanie Olson, assistant professor of earth, atmospheric, and planetary sciences, have recently found that the presence of salt in seawater can also have a major impact on the habitability of Earth and other planets.

The Purdue team modeled the effects of salinity and found that increases or decreases in ocean salt concentration have profound effects on habitability. Their paper, by Olson et al., “The Effect of Ocean Salinity on Climate and Its Implications for Earth’s Habitability,” was published open access in Geophysical Research Letters.

The influence of atmospheric composition on the climates of present-day and early Earth has been studied extensively, but the role of ocean composition has received less attention.

A major finding in the paper is that high salinity warms the climate by affecting ocean currents. This may answer, the authors believe, the faint young sun paradox: i.e., how our planet avoided the Snowball Earth scenario when the solar luminosity (solar energy per unit area, in watts per square meter) was 20 percent lower, according to theories of stellar evolution for G2 main sequence stars like our sun.

We find that saltier oceans yield warmer climates in large part due to changes in ocean dynamics. Increasing ocean salinity from 20 to 50 g/kg results in a 71% reduction in sea ice cover in our present-day Earth scenario. This same salinity change also halves the pCO2 threshold at which Snowball glaciation occurs in our Archean scenarios. In combination with higher levels of greenhouse gases such as CO2 and CH4, a saltier ocean may allow for a warm Archean Earth with only seasonal ice at the poles despite receiving ∼20% less energy from the Sun.

Ecological Consequences

Too much salt, on the other hand, can be hostile to life. Watch plant roots bend to avoid salt in a news item from the University of Copenhagen. The Purdue authors did not consider the effects on organisms with 50g/kg NaCl (their highest model value). Some organisms are remarkably salt-tolerant now, but evolutionists do not think they began that way. The Dead Sea, with over 340 g/kg, is dead for a reason. Rising salinity in California’s Salton Sea has killed most of the fish that once attracted anglers to its shores (Desert Sun). On Mars, the pervasive concentration of perchlorate salts worries some astrobiologists about the possibility of life there.

Other consequences of changes in salinity not discussed by the paper in detail include interactions with other ions and elements critical for life. Tinkering with salt is likely to cause unintended consequences.

Fine Timing

The paper’s conclusions rest on assumptions that are difficult to test and are somewhat dubious. For instance, modeling high salt concentration initially to keep the planet from freezing under a cooler sun could appear like special pleading; how do they know salt concentrations did not start initially low instead, increasing as water eroded the continents? Do they have an experimental basis for presuming higher salinity in the past? They cite a couple of papers, but note that

Archean salinity remains poorly constrained. Our goal is thus not to offer a definitive view of a single moment in Earth’s history; instead, our goal is simply to explore the response of the climate system to changing ocean salinity and to assess the potential significance of these effects in the context of reduced solar luminosity on early Earth.

More important for a design view of the Earth is the relation between salinity and habitability. Is the value of 35g/Kg NaCl a “Goldilocks” value? Has the salinity value remained stable while life was present, but fluctuated, increased monotonically, or decreased prior to life’s appearance? If both questions yield affirmative answers, there might be evidence of fine timing to consider, a possible homeostasis in salt geology as well as salt biology. Notice the delicate balance that results from changes in salinity, according to the authors:

Present-day seawater with a salinity of 35 g/kg freezes (and is most dense) at −1.9°C, and saltier oceans freeze at progressively lower temperatures. In combination, these three density effects may profoundly affect the density structure of the ocean, its circulation, and ocean heat transport to high latitudes with consequences for sea ice formation. Even small differences in sea ice formation may yield significant climate differences through interaction with the positive ice-albedo feedback.

Then the authors point out that salinity is a dynamic value. It thus becomes crucial to understand the sources and sinks of salt.

Sodium (Na+) and chlorine (Cl−) are the primary ions contributing to ocean salinity today. The residence times of Na+ and Cl− ions in the ocean are 80 and 98 Myr, respectively, much shorter than the age of the Earth.

The authors point out that salinity also affects the concentration of atmospheric CO2. This becomes another complication not previously considered in climate models. Notice the word “coincidence” in this eye-opening statement:

The salinity evolution of Earth’s ocean is not yet well constrained, but constant salinity through time would be a notable coincidence or imply some currently unknown feedback. Climate models that implicitly assume present-day salinity may thus yield misleading views of Earth’s climate history.

The paper raises interesting new questions more than it provides definitive answers:

It is thus unclear whether accounting for changes to sea salt aerosol in our model would have a large effect on climate and whether these effects would amplify or offset warming with increasing salinity in our model scenarios. The relationships between ocean salinity, atmospheric water vapor, cloud nucleation, precipitation patterns, and surface temperature on short and long timescales remain an exciting opportunity for future work.

A Critical Role

That’s enough quotation to point out the criticality of salt to habitability. Those interested in the details can follow the authors’ arguments in the paper. Suffice it to say that a planet designer would have had to regulate an additional factor — salt — to make it livable. Liquid water alone is not enough to maintain a CHZ. One cannot tinker recklessly with salt concentration without knocking a planet out of the Goldilocks zone. If the models require beginning with a cooler sun, was it a lucky coincidence to start with higher salinity to keep the Earth warm, then decrease it steadily as the sun brightened?

The Purdue research adds two factors to the list of requirements for habitability that Denton, Gonzalez, Richards and others have compiled: (1) fine tuning of salt concentrations for a stable climate, and (2) fine timing of salt dynamics under a changing solar constant. Maybe there is something new under the sun after all: the salt of the Earth.

Monday 19 December 2022

The latest in our unending search for straight answers.

Exodus5:2ASV"And Pharaoh said, Who( Not what) is JEHOVAH...?"

Can any trinitarian give us a straight answer to Pharaoh's querie?

Darwinism's failure as a predictive model.XVII

Darwinism's predictions

Cornelius G Hunter

Just as evolution predicts that gene trees and species trees should be congruent, it also predicts that different gene trees should be congruent. In 1982 David Penny and co-workers tested this prediction. They wrote that “The theory of evolution predicts that similar phylogenetic trees should be obtained from different sets of character data.” Their character data came from five different proteins and they concluded “there is strong support from these five sequences for the theory of evolution.” (Penny, Foulds and Hendy) But in later years, as more genetic data became available, it was clear that different genes led to very different evolutionary trees. As one study explained, the sequences of genes, “often disagree and can seldom be proven to agree.” (Doolittle and Bapteste) It is now well understood that “Gene and genome trees conflict at many levels” (Haggerty, et. al.) and that “Incongruence between gene trees is the main challenge faced by phylogeneticists in the genomic era.” (Galtier and Daubin) For evolutionists this failed prediction will require more complicated models of evolutionary history. As Penny now writes, he is “not rejecting the tree per se but enriching the tree concept into a network.” (Penny)

References

Doolittle, W., E. Bapteste. 2007. “Pattern pluralism and the Tree of Life hypothesis.” Proceedings of the National Academy of Sciences 104:2043-2049.

Galtier, N., V. Daubin. 2008. “Dealing with incongruence in phylogenomic analyses.” Philosophical Transactions of the Royal Society B 363:4023-4029.

Haggerty, L., et. al. 2009. “Gene and genome trees conflict at many levels.” Philosophical Transactions of the Royal Society B 364:2209-2219.

Penny, D. 2011. “Darwin’s Theory of Descent with Modification, versus the Biblical Tree of Life.” PLoS Biol 9:e1001096.

Penny, D., L. Foulds, M. Hendy. 1982. “Testing the theory of evolution by comparing phylogenetic trees constructed from five different protein sequences.” Nature 297:197-200.

Hope has fallen?

Bioethicist: Having Children Is Bad

Wesley J. Smith

This is the world of bioethics, the “experts” whom we are supposed to trust to guide public policy on a range of issues, from medical policy to environmental law.

We should not listen to a word the mainstreamers have to say — as this article telling us not to have children makes clear. From “Science Proves Kids are Bad for the Earth,” by Travis Reider, published at NBC Think:

A startling and honestly distressing view is beginning to receive serious consideration in both academic and popular discussions of climate change ethics. According to this view, having a child is a major contributor to climate change. The logical takeaway here is that everyone on Earth ought to consider having fewer children.

The Chinese Model

Talk about shades of China family-planning theory. We must destroy much of what makes life worth living in order save the planet!

The argument that having a child adds to one’s carbon footprint depends on the view that each of us has a personal carbon ledger for which we are responsible. Furthermore, some amount of an offspring’s emissions count towards the parents’ ledger.

Whatcrap. We do not have to feel guilty for being alive. Moreover, children bring great joy into the world. They are the posterity to whom the future will belong and depend. They are the hope of the world, not environmental disasters.

The Most Important Endeavor

If I release a murderer from prison, knowing full well that he intends to kill innocent people, then I bear some responsibility for those deaths — even though the killer is also fully responsible. My having released him doesn’t make him less responsible (he did it!). But his doing it doesn’t eliminate my responsibility either.

Something similar is true, I think, when it comes to having children: Once my daughter is an autonomous agent, she will be responsible for her emissions. But that doesn’t negate my responsibility. Moral responsibility simply isn’t mathematical. . . .

Having a child imposes high emissions on the world, while the parents get the benefit. So like with any high-cost luxury, we should limit our indulgence.

No. Choosing to bring new life is not an environmental wrong. It is the best that life has to offer.

This is why I call it global-warming hysteria. And it’s an example of why I think most bioethics discourse pushes us away from policies and actions that make for a healthy and vibrant society.

Ps. Luke23:29NIV"For the time will come when you will say, ‘Blessed are the childless women, the wombs that never bore and the breasts that never nursed!’"

For the record I believe that both the author and the mainstream bioethicists he vehemently opposes mean well but they both attacking the symptoms and not the disease.

Sunday 18 December 2022

Darwinism's failure as a predictive model XVI

Darwinism's predictions

Cornelius G Hunter

Evolution predicts that genetic change drives evolutionary change. Genetic changes that confer improved fitness are more likely to be selected and passed on. All of this means that evolutionary trees based on comparisons of genes should be similar, or congruent, with evolutionary trees based on comparisons of the entire species. Simply put, gene trees and species trees should be congruent. But while this has often been claimed to be a successful prediction, it is now known to be false. As one study explained, “Perhaps most unexpected of all is the substantial decoupling, now known in most, although not all, branches of organismal life, between the phylogenetic histories of individual gene families and what has generally been accepted to be the history of genomes and/or their cellular or organismal host lineages.” (Ragan, McInerney and Lake)

The molecular and the visible (morphological) features often indicate “strikingly different” evolutionary trees that cannot be explained as due to different methods being used. (Lockhart and Cameron) Making sense of these differences between the molecular and the morphological features has become a major task, (Gura) so common that it now has its own name: reconciliation. (Stolzer, et. al.)

The growing gap between molecular analyses and the fossil record, concluded one researcher, “is astounding.” (Feduccia) Instead of a single evolutionary tree emerging from the data, there is a wealth of competing evolutionary trees. (de Jong) And while the inconsistencies between molecular and fossil data were, if anything, expected to be worse with the more ancient, lower, parts of the evolutionary tree, the opposite pattern is observed. As one study explained, “discord between molecular divergence estimates and the fossil record is pervasive across clades and of consistently higher magnitude for younger clades.” (Ksepka, Ware and Lamm)

References

De Jong, W. 1998. “Molecules remodel the mammalian tree.” Trends in Ecology & Evolution, 13:270-275.

Feduccia, A. 2003. “‘Big bang’ for tertiary birds?.” Trends in Ecology & Evolution 18:175.

Gura, T. 2000. “Bones, molecules...or both?.” Nature 406:230-233.

Ksepka, D. T., J. L. Ware, K. S. Lamm. 2014. “Flying rocks and flying clocks: disparity in fossil and molecular dates for birds.” Proceedings of the Royal Society B 281: 20140677.

Lockhart, P., S. Cameron. 2001 “Trees for bees.” Trends in Ecology and Evolution 16:84-88.

Ragan, M., J. McInerney, J. Lake. 2009. “The network of life: genome beginnings and evolution.” Philosophical Transactions of the Royal Society B 364:2169-2175.

Stolzer, M., et. al. 2012. “Inferring duplications, losses, transfers and incomplete lineage sorting with nonbinary species trees.” Bioinformatics 28 ECCB:i409–i415.

Saturday 17 December 2022

Between the magic kingdom and JEHOVAH's Kingdom.

On this classic ID the future, John West, author of Walt Disney and Live Action: The Disney Studio’s Live-Action Features of the 1950s and 60s, talks about Walt Disney’s life-long fascination with evolution. By exploring various messages embedded in Disney’s theme parks and animated features, from the Magic Skyway created for the 1964 World’s Fair to the 1948 animated film Fantasia, we see Disney’s recurring contemplation of evolution. Fantasia, in particular, provides an extended depiction of evolutionary history along with imaginatively rendered reflections on rationalism, materialism, and animism. At first blush Fantasia’s “Rite of Spring” seems to promote Darwinian materialism, but as West explains, a closer look reveals considerable nuance and ambiguity. On the Magic Skyway, animatronics were used to tell stories of ages past, from the age of the dinosaurs to the arrival of man. Disney’s presentation there skirted the origins of humans but, as West argues, the narration suggests that humanity is something qualitatively different, a message at odds with Darwinian materialism.

While we have you here, please consider an end-of-year gift to Discovery Institute’s Center for Science and Culture (CSC) to support this podcast and the culture-impacting work of intelligent design. The research and writing of CSC fellows such as Stephen Meyer, Michael Behe, Jonathan Wells, Casey Luskin, and Ann Gauger are pushing back the darkness that is Darwinian materialism. The CSC’s work is also shining a light on the truth that nature is a work of genius and that we are, indeed, fearfully and wonderfully made. Click here to give

Darwinism's failure as a predictive model XV

Darwinism's predictions

fundamental concept in evolutionary theory is the inheritance of genetic variations via blood lines. (Forbes) This so-called vertical transmission of heritable material means that genes, and genomes in general, should fall into a common descent pattern, consistent with the evolutionary tree. Indeed, such genes are often cited as a confirmation of evolution. But as more genomic data have become available, an ever increasing number of genes have been discovered that do not fit the common descent pattern because they are missing from so many intermediate species. (Andersson and Roger 2002; Andersson and Roger 2003; Andersson 2005; Andersson, Sarchfield and Roger 2005; Andersson 2006; Andersson et. al. 2006; Andersson 2009; Andersson 2011; Haegeman, Jones and Danchin; Katz; Keeling and Palmer; Richards et. al 2006a; Richards et. al 2006b; Takishita et. al.; Wolf et. al.)

This type of pattern is also found for genome architecture features which are sporadically distributed and then strikingly similar in distant species. In fact these similarities do not merely occur twice, in two distant species. They often occur repeatedly in a variety of otherwise distant species. This is so widespread that evolutionists have named the phenomenon “recurrent evolution.” As one paper explains, the recent explosion of genome data reveals “strikingly similar genomic features in different lineages.” Furthermore, there are “traits whose distribution is ‘scattered’ across the evolutionary tree, indicating repeated independent evolution of similar genomic features in different lineages.” (Maeso, Roy and Irimia)

One example is the uncanny similarity between the kangaroo and human genomes. As one evolutionist explained: “There are a few differences, we have a few more of this, a few less of that, but they are the same genes and a lot of them are in the same order. We thought they’d be completely scrambled, but they’re not.” (Taylor)

It is now well recognized that this prediction has failed: “Vertical transmission of heritable material, a cornerstone of the Darwinian theory of evolution, is inadequate to describe the evolution of eukaryotes, particularly microbial eukaryotes.” (Katz) And these sporadic, patchy patterns require complicated and ad hoc scenarios to explain their origin. As one paper explained, the evolution of a particular set of genes “reveals a complex history of horizontal gene transfer events.” (Wolf et. al.) The result is that any pattern can be explained by arranging the right mechanisms. Features that are shared between similar species can be interpreted as “the result of a common evolutionary history,” and features that are not can be interpreted as “the result of common evolutionary forces.” (Maeso, Roy and Irimia)

These common evolutionary forces are complex and must have been created by evolution. They can include horizontal (or lateral) gene transfer, gene loss, gene fusion, and even unknown forces. For instance, one study concluded that the best explanation for the pattern of a particular gene was that it “has been laterally transferred among phylogenetically diverged eukaryotes through an unknown mechanism.” (Takishita et. al.) Even with the great variety of mechanisms available, there still remains the unknown mechanism.

References

Home

Introduction

Why investigate evolution’s false predictions?

Responses to common objections

Early evolution predictions

The DNA code is not unique

The cell’s fundamental molecules are universal

Evolutionary causes predictions

Mutations are not adaptive

Competition is greatest between neighbors

Molecular evolution predictions

Protein evolution

Histone proteins cannot tolerate much change

The molecular clock keeps evolutionary time

Common descent predictions

The pentadactyl pattern and common descent

Serological tests reveal evolutionary relationships

Biology is not lineage specific

Similar species share similar genes

MicroRNA

Evolutionary phylogenies predictions

Genomic features are not sporadically distributed

Gene and host phylogenies are congruent

Gene phylogenies are congruent

The species should form an evolutionary tree

Evolutionary pathways predictions

Complex structures evolved from simpler structures

Structures do not evolve before there is a need for them

Functionally unconstrained DNA is not conserved

Nature does not make leaps

Biological architecture predictions

Behavior

Altruism

Cell death

Conclusions

What false predictions tell us about evolution

Genomic features are not sporadically distributed

A fundamental concept in evolutionary theory is the inheritance of genetic variations via blood lines. (Forbes) This so-called vertical transmission of heritable material means that genes, and genomes in general, should fall into a common descent pattern, consistent with the evolutionary tree. Indeed, such genes are often cited as a confirmation of evolution. But as more genomic data have become available, an ever increasing number of genes have been discovered that do not fit the common descent pattern because they are missing from so many intermediate species. (Andersson and Roger 2002; Andersson and Roger 2003; Andersson 2005; Andersson, Sarchfield and Roger 2005; Andersson 2006; Andersson et. al. 2006; Andersson 2009; Andersson 2011; Haegeman, Jones and Danchin; Katz; Keeling and Palmer; Richards et. al 2006a; Richards et. al 2006b; Takishita et. al.; Wolf et. al.)

References

Andersson, J., A. Roger. 2002. “Evolutionary analyses of the small subunit of glutamate synthase: gene order conservation, gene fusions, and prokaryote-to-eukaryote lateral gene transfers.” Eukaryotic Cell 1:304-310.

Andersson, J., A. Roger. 2003. “Evolution of glutamate dehydrogenase genes: evidence for lateral gene transfer within and between prokaryotes and eukaryotes.” BMC Evolutionary Biology 3:14.

Andersson, J. 2005. “Lateral gene transfer in eukaryotes.” Cellular and Molecular Life Sciences 62:1182-97.

Andersson, J., S. Sarchfield, A Roger. 2005. “Gene transfers from nanoarchaeota to an ancestor of diplomonads and parabasalids.” Molecular Biology and Evolution 22:85-90.

Andersson, J. 2006. “Convergent evolution: gene sharing by eukaryotic plant pathogens.” Current Biology 16:R804-R806.

Andersson, J., R. Hirt, P. Foster, A. Roger. 2006. “Evolution of four gene families with patchy phylogenetic distributions: influx of genes into protist genomes.” BMC Evolutionary Biology 6:27.

Andersson, J. 2009. “Horizontal gene transfer between microbial eukaryotes.” Methods in Molecular Biology 532:473-487.

Andersson, J. 2011. “Evolution of patchily distributed proteins shared between eukaryotes and prokaryotes: Dictyostelium as a case study.” J Molecular Microbiology and Biotechnology 20:83-95.

Haegeman, A., J. Jones, E. Danchin. 2011. “Horizontal gene transfer in nematodes: a catalyst for plant parasitism?.” Molecular Plant-Microbe Interactions 24:879-87.

Katz, L. 2002. “Lateral gene transfers and the evolution of eukaryotes: theories and data.” International J. Systematic and Evolutionary Microbiology 52:1893-1900.

Keeling, P., J. Palmer. 2008. “Horizontal gene transfer in eukaryotic evolution,” Nature Reviews Genetics 9:605-18.

Maeso, I, S. Roy, M. Irimia. 2012. “Widespread Recurrent Evolution of Genomic Features.” Genome Biology and Evolution 4:486-500.

Richards, T., J. Dacks, J. Jenkinson, C. Thornton, N. Talbot. 2006. “Evolution of filamentous plant pathogens: gene exchange across eukaryotic kingdoms.” Current Biology 16:1857-1864.

Richards, T., J. Dacks, S. Campbell, J. Blanchard, P. Foster, R. McLeod, C. Roberts. 2006. “Evolutionary origins of the eukaryotic shikimate pathway: gene fusions, horizontal gene transfer, and endosymbiotic replacements.” Eukaryotic Cell 5:1517-31.

Takishita, K., Y. Chikaraishi, M. Leger, E. Kim, A. Yabuki, N. Ohkouchi, A. Roger. 2012. “Lateral transfer of tetrahymanol-synthesizing genes has allowed multiple diverse eukaryote lineages to independently adapt to environments without oxygen.” Biology Direct 7:5.

Taylor, R. 2008. “Kangaroo genes close to humans,” Reuters, Canberra, Nov 18.

Wolf, Y., L. Aravind, N. Grishin, E. Koonin. 1999. “Evolution of aminoacyl-tRNA synthetases--analysis of unique domain architectures and phylogenetic trees reveals a complex history of horizontal gene transfer events.” Genome Research 9:689-710.

Friday 16 December 2022

Time for mankind to take a shot at designed intelligence?

Can a Dog Be Bred to Be as Smart as a Human?

Denyse O'Leary

Within one hundred generations or roughly 600 years? That’s the project Payton Pearson, an electrical engineer who gives his affiliation as the Air Force Institute of Technology in Dayton, Ohio, has set himself:

Artificial selection is a well-known phenomenon of selecting for certain physiological characteristics of various species of plants and animals, and it is something that human beings have been doing for thousands of years. A perfect example of this is the union and development of dogs under human stewardship since the beginning of the agricultural era of society. In that time, approximately 6,000 years [1], dogs have been artificially selected in such a way as to produce thousands of different breeds. From the stout Dachshund, a dog breed produced for the purpose of hunting den-dwelling animals, to the highly intelligent Border Collies who were bred to help sheep herders herd their flocks; the many different canine breeds have served humanity in a multitude of capacities for many generations. In this paper, using the concept of artificial selection,[1] it is determined with mathematical and statistical evidence how humans could artificially select for canine intelligence to such a degree as to produce canines with human levels of intelligence within a relatively short amount of time — 600 years.