Life's Other Secret: The New Mathematics of the Living World [Hardcover]

Ian Stewart (Author)

Book Description

Publication Date: December 22, 1997 | ISBN-10: 0471158453 | ISBN-13: 978-0471158455 | Edition: 1

Is there an underlying set of principles that connects the pattern of a tiger's stripes with the design of a butterfly's wings? Are there hidden laws of life that lie deeper than DNA?

According to award-winning science writer Ian Stewart, the answer is yes, and the hidden rules are called mathematics. In Life's Other Secret, Stewart exploits a realm of pattern and beauty that links the pulse of life with the creative enterprise of mathematics.

Pointing to what he describes as an exaggerated emphasis on the power of DNA in determining the shape and behavior of life-forms, Stewart compares DNA to a recipe book of ingredients, quantities, and sequences: very useful, but far from a complete plan of the final result. Beneath the genes lies the rich texture of the physical universe with its deep patterns, forms, structures, processes, and systems—a world of infinite subtlety that can be described only through mathematics. Genes may move a life-form in a specific direction, but it is the mathematical laws of chemistry and physics that control an organism's response to its genetic instructions.

With the visionary work of the zoologist D'Arcy Thompson as his touchstone, Stewart unfolds a series of dazzling mathematical patterns in the organic world: the ethereal spiral of the nautilus shell, the fluid forms of a jellyfish, the boastful beauty of the peacock's tail, and the amazing numerology of floral petals. He leads us to a place where number and nature coalesce, and where the order of mathematics manifests itself in life.

Life's Other Secret teems with surprising insights. Stewart describes how complexity theory may help explain the origin and evolution of life, and how the Fibonacci number sequence of 1, 2, 3, 5, 8, 13, 21, 34 seems to rule the number of petals, stamens, and other parts of most plant life. He traces the mathematical patterns of locomotion through the broad range of limbs, wings, muscles, and fins. We learn about hidden mathematical order in flocks of birds, crowds of humans, and in the firing patterns of fireflies. The very nerve cells that relay the perception of these natural phenomena to the brain are most accurately described by mathematical models.

Through this eye-opening tour of an exciting new area of research, we perceive a growing sense of the wonders that will come out of a union of biology and mathematics, a union that will provide a deeper comprehension of the fundamental forces of life.

An invitation to a hidden world

In Life's Other Secret, mathematician and award-winning science writer Ian Stewart reveals the way mathematics describes the origin, structure, and evolution of life. With an abundance of illustrations, many in color, here is an intriguing invitation to enter a world deeper than DNA, a world where number series bloom in the spring and equations gallop across the plains.

"From one of mathematics' most gifted expositors . . . challenging and interesting. . . . Those with no knowledge of the subject will be able to glimpse its beauty and appeal." —New Scientist

Praise for Nature's Numbers

"An example of first-rate popular mathematics writing. . . . Stewart achieves what other popular writers merely strive for." —Nature

Editorial Reviews

From Library Journal

While long an indispensable tool for the physical sciences, mathematics has only relatively recently been used to describe the symmetry of the living world. Stewart sees mathematical laws at work even at the level of DNA replication.
Copyright 1999 Reed Business Information, Inc.

From Scientific American

Life's first secret, Stewart says, is the molecular structure of DNA. The other secret, he believes, is mathematical control of a growing organism. (Mathematician Stewart's activities include conducting this magazine's Mathematical Recreations department.) Arguing that "life is a partnership between genes and mathematics," he embarks on an absorbing study of what life is, how it originated and how the search for mathematical laws that underlie the behavior of living organisms will illuminate those deep questions. Along the way, he examines mathematical patterns in flowers, bird feathers, animal locomotion and many other features of life. But he hopes for much more profound findings in biomathematics. "A full understanding of life depends on mathematics," he writes. "At every level of scale, from molecules to ecosystems, we find mathematical patterns in innumerable aspects of life. It is time we put the mathematics and the biology together." --This text refers to the Paperback edition.

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Product Details

• Hardcover: 304 pages
• Publisher: Wiley; 1 edition (December 22, 1997)
• Language: English
• ISBN-10: 0471158453
• ISBN-13: 978-0471158455
• Product Dimensions: 9.3 x 6 x 1.3 inches
• Shipping Weight: 1.5 pounds
• Average Customer Review: 4.0 out of 5 stars  See all reviews (7 customer reviews)
• Amazon Best Sellers Rank: #2,320,568 in Books (See Top 100 in Books)

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28 of 30 people found the following review helpful:

5.0 out of 5 stars DNA may not be the last word, March 18, 2000

By 

Duwayne Anderson (Saint Helens, Oregon) - See all my reviews
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This review is from: Life's Other Secret: The New Mathematics of the Living World (Paperback)

Stewart begins his book by telling the reader:

"I am going to try to convince you that as wonderful as genes are, they are not the whole answer to the question of life. More radically, I am also going to try to convince you that a full understanding of life depends upon mathematics."

Basically, Stewart believes that scientists have overemphasized genetics and ignored (or at least under emphasized) the role of what I'll call large-scale or macro rules of physics and chemistry and the comparatively simple mathematics that describe them. For example, a molecular biologist might see a striped shell and wonder which genes caused them. Stewart would be more inclined to ask if there isn't some sort of chemical diffusion equation that leads to the stripes without them being specifically encoded in the genes. The point is that DNA may not need to encode much detail in many cases because the detail arises spontaneously out of macroscopic laws.

Stewart has studied at the Santa Fe Institute in New Mexico. Other prominent scientists associated with the Institute are Murray Gell-Mann and Stuart Kauffman. Kauffman, in particular, has conducted studies regarding emergent properties of self-catalytic systems and you can see the influence of his thinking in much of Ian Stewart's book (see Stuart Kauffman's book "At home in the universe, the search for laws of self organization and complexity").

The book begins with discussions relating to the nature of life and musings about DNA and replication. It's interesting to see the line between life and non-life blur under Stewart's prose. Chapter three discusses the emergence of DNA, possible roles played by clay platelets, and the idea that DNA might be just a frozen accident - the molecule was picked because it evolved first and created an environment in which no others could get a start once DNA was established.

Chapter four is called the oxygen menace. There is an interesting discussion of how prokaryotes might have evolved, created oxygen as a poisonous byproduct, oxygenated the atmosphere, and then evolved into eukaryotes to capitalize on a more efficient method of generating energy by burning fuel using oxygen in the new atmosphere. This chapter has some interesting stuff on how cells move using the cytoskeleton and microtubules. I also enjoyed the description of slime-mold colonies and how they illustrate the possible manner in which larger organisms evolved from cooperative colonies of less complex life forms.

Chapter five is titled artificial life, but much of it deals strictly with the process of evolution among very un-artifical forms. There is a discussion about the famous finches on the Galapagos Islands and how they stimulated Darwin to understand how species evolve. There is also some interesting material on numerical taxonomy, evolutionary taxonomy, and cladism. Finally, the end of the chapter distills the discussion into general principles of evolution and how simple computer programs (artificial life) can illustrate many of the patterns we see in the real world among living species.

The first five chapters are really just background information about the first life on our planet, the evolution of DNA, and general principles of evolution. Stewart's real thesis (and the real fun) begins in chapter 6 with flowers for Fibonacci. Ever wonder why the seeds in a sunflower spiral the way they do? Ever wonder why there are the numbers of petals you find in flowers? Chapter 6 has the surprisingly simple answer, and it doesn't require lots of information encoding in DNA sequences, either.

Chapter 7 is a little more controversial than chapter 6. It attempts to show that patterns in living organisms might not be specifically encoded in DNA, but might result from gradient chemical reactions and diffusion in some species. In other words, DNA only needs to encode the production of the right chemicals at the right time and macroscopic rules using rather simple mathematics do the rest.

Chapter 8 deals with speculation about sexual selection and how it relates to such things as the peacock's tail. In this chapter Stewart argues that in many instances the thing that is being selected is actually symmetry. Asymmetry can be a sign of a damaged or defective organism. The thing I enjoyed most from this chapter was the discussion about common hallucinations and how they might result from the way simple plane waves in the visual cortex map into our retina.

Chapter 9 was my favorite. It describes hypothetical harmonic generators that work together in various relative relationships of phase and attenuation to produce the natural gaits of quadrupeds and even bipeds. Stewart has done original work in this area, and so this chapter has some of the most insight and technical backup. I've often wondered about this myself and contemplated the possibility that such natural harmonic generators might be somehow related to the tendency of our species to develop certain musical beats and to naturally move in rhythm with them.

Of course you will want to read chapter ten, which shows how rather simple rules can lead to rather complex looking spider webs. And don't forget to read chapter 11 which discusses the complex interrelationships of reefs, along with some rather interesting information regarding Von Neumann's amazing insights.

This isn't a book on mathematics - it's a book about how mathematics applies to biology. And it's mostly qualitative. There are no mathematical equations, for example.

Overall, I think this is a first-rate book. It's well written, engaging, has a complete index, copious notes, good figures, and brilliant color plates that I especially appreciated. You don't have to agree with everything Stewart has to say, but I think you will find his arguments intriguing, thought provoking, and stimulating regardless. If you love life and mathematics, this book should be in your library.

Duwayne Anderson, March 18, 2000

10 of 12 people found the following review helpful:

5.0 out of 5 stars Math Rules, January 29, 2003

By 

Albert Swanson (Seattle, WA United States) - See all my reviews

This review is from: Life's Other Secret: The New Mathematics of the Living World (Paperback)

Is life regulated and given structure by genetics alone? Or do physical and chemical constraints have a significant bearing on an organism's morphology? Inspired by D'Arcy Wentworth Thompson's classic, On Growth and Form, mathematician Ian Stewart argues convincingly that, the current popular view of the primacy of the genome notwithstanding, the major phenotypical influences, including those of the genes themselves, are highly constrained by physics and chemistry, both as endogenous and exogenous processes. What's more, such processes are manifestations of underlying mathematical "rules". (Stewart is, of course, neither the first nor the last to champion the "life is math" viewpoint. Other strange bedfellows in this general tradition range from William Paley, the eighteenth century theologian who conceived a mechanical universe so finely crafted and tuned that there must be a (divine) "watchmaker", to Stephen Wolfram, whose recent vanity tome, A New Kind of Science, posits, at its core, cellular automata as life's computing mechanism.)

Life's Other Secret is a beautifully written book that teaches about symmetry and symmetry breaking and oscillators and other important facets of evolution's geometry. It might seem odd that a mathematician takes on a subject more apparently appropriate to biology or zoology. And, indeed, life does often imitate art: In Collapse of Chaos, Stewart and Jack Cohen provide an example destructive professional encroachment: Two ice cream venders at the beach increasingly move in on each other's territory, so that, in the end, neither the bank accounts of the venders nor the gustatory desires of their customers are best served. Yet, in a more complete sense, the idea of bringing the weight of mathematics to bear on diverse disciplines is firmly in the tradition of "the unity of all knowledge". This concept (which Edward O. Wilson identifies as "consilience") held scholarly sway prior to the fairly recent "symmetry breaking" among the sciences: the ultra-specialization desired for engineering and for academic dissertations. A return to the renaissance approach is truly a breath of fresh air.

Life's Other Secret is also a curiously non-technical book that should present few challenges to those with math anxiety. This is, in fact, a conscious part of Stewart's message. In the spirit of the late physicist Richard Feynman, Stewart promotes qualitative math (as opposed to the more common idea of quantitative math, which Life's Other Secret studiously avoids) not as "vague generalities", but as "features that are conceptually deeper than mere numbers."

To me, one characteristic of good writing (both fiction and nonfiction) is that the reader is led to extrapolate and go off on personal tangents. Here are two possible directions for speculation. The positing of "rules-based evolution" raises the further question of whether these rules are artifactual emergences out of evolutionary dynamics, or whether they were set down by a Great Designer, ere the worlds began to be. And, secondly, how, specifically, do biological entities implement the math? That is, how do organisms "compute"? What are the "algorithms" of life?

My only criticism is the lack of appendices where concepts such as spherical harmonics, field functions, and other technical matters could be discussed in more detail without tromping on the narrative. But this is, to me, a minor carp. In Life's Other Secret, Stewart is clearly a master expositor at the top of his form.

7 of 8 people found the following review helpful:

5.0 out of 5 stars Lots of interesting ideas about how Life works, April 11, 1999

By 

Kurt W. Swenson (Portland, OR) - See all my reviews
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Amazon Verified Purchase

This review is from: Life's Other Secret: The New Mathematics of the Living World (Hardcover)

This book is about biomathemetics for those of us who didn't know we were interested in biomathematics. Stewart teases us into the subject by exploring different contexts for the question of "What is Life?". This leads to explorations into how life is shaped by the properties of physical laws. The book focuses on abstractions. Stewart talks about ideas, but chooses not to go into much detail. Many of the illustrations have no explanations, and some have errors. The ideas are all clearly related, but they are never really tied together in the book. I think this was intentional. I think Stewart is hoping that the theme of the book will emerge from the ideas. If he had tried to state the theme as a conclusion that tied the ideas all together, the theme would belong to the author. He wants the theme to belong to the reader, and so he let's us come to our own conclusions. This leaves you with an unfinished feeling, but there are lots of good references (I especially like his annotated further reading section). I feel wiser for having read this book. The most confusing part of the book comes from using the name "math" to describe the language of numbers and as a notation for describing symmetries in the physical universe.