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升级    99.43% TA的每日心情 | 擦汗
2016-1-30 03:42 |
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签到天数: 1 天 [LV.1]初来乍到
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英文原文:<br/>2.1 The essential idea of Autopoiesis<br/>$ K+ o! I/ C' n, K
The fundamental question Maturana and Varela set out to answer is: what, H4 e. O- F- N0 o8 V
distinguishes entities or systems that we would call living from other) @- t6 G6 Z" }
systems, apparently equally complex, which we would not? How, for
6 B/ s, M" ^4 n# M: d/ r+ D# vexample, should a Martian distinguish between a horse and a car? This- {; {' y& h$ V( p9 b
is an example that Monod (1974, p. 19) uses in addressing the similar6 y* } A& [4 s( q* f
but not identical question of distinguishing between natural and
% Y+ o p, _- X, \artificial systems.<br/>
" E6 {6 b, r5 C. ?* GThis has always been a problem for biologists, who have developed a# H( r+ s+ @: Y" i; G% J# i8 u
variety of answers. First came vitalism (Bergson, 1911; Driesch, 1908),
+ ]+ Z$ L% P9 m9 Cwhich held that there is some substance or force or principle, as yet1 l& M1 ^4 A' ^& o' f$ v. V2 w& q6 B
unobserved, which must account for the peculiar characteristics of3 d6 w* L9 c6 o5 ]0 t" k
life. Then system theory, with the development of concepts such as5 F% T/ p! g1 H+ @1 f
feedback, homeostasis, and open systems, paved the way for explanations
' M" n$ i; u4 q# f$ F! `0 nof the complex, goal-seeking behavior of organisms in purely5 l8 m" |' i+ b' r1 m' @0 u5 E
mechanistic term ( for example, Cannon, 1939; Priban, 1968). While this
9 ~' R, {: V5 [2 h4 D* S8 a, `was a significant advance, such mechanisms could equally well be built( `5 V" K5 e$ q- G6 |+ S
into simple machines that would never qualify as living organisms.<br/>
' `( n% Z3 n, g) ?9 xA third approach, the most common recently, is to specify a list of
1 H0 U8 k5 n8 `3 W" ^2 Nnecessary characteristics that any living organism must have – such as9 _. p$ f% _/ Q! m$ g1 y
reproductive ability, information-processing capabilities, carbon-based/ g' }( X8 u' y1 \( r, D
chemistry, and nucleic acids (see, for example, Miller, 1978; Bunge,/ T. c/ ~) g2 y! ?* [5 D
1979). The first difficulty with this approach is that it is entirely' M ]3 k+ @6 m6 [9 v
descriptive and not in any real sense explanatory. It works by
, Z* b% `& u0 S, A% S& {- @observing systems that are accepted as living and noting some of their
* p# c/ x" @; g, \8 E. [+ w0 U' Ccommon characteristics. However, this tactic assumes precisely that: J0 u- U- F& m) u# t
which is in need of explanation – the distinction between the living2 |* a5 n% v- T5 y; x2 B
and the nonliving. The approach fails to define the characteristics6 E1 E& c" `5 P. c& W) P! P- i# c
particular to living systems alone or to give any explanation as to how/ p* D' r0 y1 o9 o
such characteristics might generate the observed phenomena. Second,
$ P$ R" a+ C0 k* W2 Q' R! t' m! Ithere is, inevitably, always a lack of agreement about the contents of0 r l) b" T/ v& b: w
such lists. Any two lists will contain different characteristics, and
" ~( }, Q% o | s- z- i: ]it is difficult to prove that every feature in a list is really
2 x; d4 j: {+ c. t: Pnecessary or that the list is actually complete.<br/>. K$ Z) x. B& W5 e" ?
Maturana’s and Varela’s work is based on a number of fundamental
$ ]0 k, F6 r p5 O* U! Xobservations about the nature of living systems. They will be
_/ v* R1 O% Q I* v% W- ?, bintroduced briefly here but discussed in more detail in later chapters.<br/>
6 X: h! v# v0 A1 Q' Q* b1. Somewhat in opposition to current trends that focus on the species5 t& Z' q* n: K) O
or the genes (Dawkins,1978), Maturana and Varela pick out the single,' Y( T& e/ s+ f* F/ w7 ~
biological individual (for instance, a single celled creature such as
. ^0 y: l6 P0 h6 qan amoeba) as the central example of a living system. One essential4 W# T0 O) k9 r. b2 _
feature of such living entities is their individual autonomy. Although& l# i9 u q; w( e: L
they are part of organisms, populations, and species and are affected6 i6 v5 x/ ]9 U$ A& g% T ?1 C' ]8 r
by their environment, individuals are bounded, self-defined entities.<br/>' L' c* w. t+ W/ E e9 q' d
2. Living systems operate in an essentially mechanistic way. They( A! U8 r' O" V. \/ P
consist of particular components that have various properties and
- w* h1 ]7 Y: B; N2 n& @. A0 f0 Minteractions. The overall behavior of the whole is generated purely by; x- _) K) i7 Q" w' n- Y# Z
these components and their properties through the interactions of
/ f: W9 c4 J* N4 [# `1 vneighboring elements. Thus any explanation of living systems must be a8 E3 z7 L! [# t
purely mechanistic one.<br/>
* q9 J" \ Q" n" B3. All explanations or descriptions are made by observers (i.e.,* W% l, ^ x G+ ?/ n$ I4 G
people) who are external to the system. One must not confuse that which
@0 p0 q* f1 Opertains to the observer with that which pertains to the observed.; o$ P9 G. S d ?0 g2 @
Observers can perceive both an entity and its environment and see how9 w( J& \+ z4 m1 z9 s
the two relate to each other. Components within an entity, however,
) f6 n8 f4 Q4 P; G3 U. N/ \9 Z7 _cannot do this, but act purely in response to other components.<br/>
: `3 A4 ^6 @/ _8 Z, S6 M( `+ O4. The last two lead to the idea that any explanation of living systems! [6 P( h8 U, a, [
should be nonteleological, i.e., it should not have recourse to ideas; {% R' b1 }+ E( }1 g
of function and purpose. The observable phenomena of living systems) ]- k# S. r1 s: j& N, A
result purely from the interactions of neighboring internal components.
9 h4 Q4 p7 s% d# IThe observation that certain parts appear to have a function with
- a4 t" C; P7 w R. F; G# cregard to the whole can be made only by an observer who can interact! b- l5 `2 R0 y1 {% z
with both the component and with the whole and describe the relation of6 b: H4 z. u) [& i) W0 k
the two.<br/>+ f. d R$ L m( v3 J8 H
<br/>
* \# [7 A3 h; ]6 `% aTo explain the nature of living systems, Maturana and Varela focus on a: b% n) s! u; a/ }
single basic example – the individual, living cell. Briefly, a cell
$ j( ?- K" I/ Y* ]consists of cell membrane or boundary enclosing various structures such& X0 ]$ K4 {& P6 l6 f
as nucleus, mitochondria, and lysosomes as well as many (and often
6 P! ?' W( H; u _7 }2 Jcomplex) molecules produced from within. These structures are in
5 N, I% {$ J, p/ fconstant chemical interplay both with each other and, in the case of+ K7 K f4 W0 B5 ^
the membrane, with their external medium. It is a dynamic, integrated
* n: Q& a+ O& t" ?& Gchemical network of incredible sophistication (see for example Alberts
7 ~7 o3 f+ }9 a( bet al.,1989; Raven and Johnson,1991).<br/># b( U4 ^( W$ }1 T5 S- U
What is it that characterizes this as an autonomous, dynamic, living
2 ?& v( c& Q" M, z6 ^whole? What distinguishes it from machine such as a chemical factory
9 B$ _" F3 x; [/ N3 ~which also consists of complex components and interacting processes of4 Y3 p/ ]/ H7 S+ w/ A. D8 t4 ^
production forming an organized whole? It can not be to do with any
3 e9 I* D* S" x; @8 Mfunctions or purposes that any single cell might fulfill in a larger
, l( H7 z7 U0 r; U* Xmulti-cellular organism since there are single-cellular organisms that4 C: `: Q. C' ^" _
survive by themselves. Nor can it explained in a reductionist way4 V6 C4 x" c4 g& ]. [
through particular structures or components of the cell such as the9 R! n5 N; Y) q/ |" I! F2 [5 c
nucleus or DNA/RNA. The difference must stem from the way of the parts- }2 f% H9 d+ R8 Z2 T
are organized as a whole. To understand Maturana and Varela’s answer,
1 ?* i+ n9 N0 F. b* ^/ k% _we need to look at two related questions – what is it that the cell
5 e/ a w% N, a) ^does, that is what is it the cell produces? And what is it that: j* o; w% R1 Q ] n+ Q* V
produces the cell? By this I mean the cell itself rather than the2 T* b9 v! Q3 L! O* ~
results of their reproduction.<br/>" y( D: l5 { X' g' m, ~6 ^! l
What does a cell do? This will be looked at in detail in Section 2.3
; ^; r+ L" v4 a6 Vbut, in essence, it produces many complex and simple substances which
8 x& P6 F% O5 W1 ?% W1 e& g5 r# Jremain in the cell (become of the cell membrane) and participate in0 e4 J" w. S' ?( B4 `
those very same production processes. Some molecules are excreted from9 \( {4 F4 y, k" l( k4 x! I$ e
the cell, through the membrane, as waste. What is it that produces the5 s+ B$ h! q7 Y; ], B. P1 Q- j
components of the cell? With the help of some basic chemicals imported
# T, \- k1 K( Gfrom its medium, the cell produces its own constituents. So a cell
7 Z- W4 p$ ?6 sproduces its own components, which are therefore what produces it in a
! c3 S- s" ^ O# k/ ccircular, ongoing process (Fig. 2.1)<br/>: }& U, K$ j; y" s
It produces, and is produced by, nothing other than itself. This simple5 [. s2 X1 u( Z1 q) i2 Y
idea is all that is meant by autopoiesis. The word means1 r# W5 w6 \; x+ ~+ X( x( p; _* |
“self-producing” and that is what the cell does: it continually
$ p/ T* o# V# i. _; [9 O- S% fproduces itself. Living systems are autopoietic – they are organized in7 ? ?0 E' s, ~5 l4 D6 T
such a way that their processes produce the very components necessary: p% U1 S3 y8 u! C
for the continuance of these processes. Systems which do not produce0 z6 W0 T# B5 T$ I
themselves are called allopoietic, meaning “other-producing” – for
8 y2 S2 _! f( bexample, a river or a crystal. Maturana and Varela also refer to
) h3 D8 r- Y! O$ i; W# [human-created systems as heteropoietic. An exemple is a chemical( w) W. K" ~/ Q* }. a
factory. Superficially, this is similar to cell, but it produces) T; R8 I6 ~2 C2 X7 E8 U8 K
chemicals that are used elsewhere, and is itself produced or maintained8 L! J: b. Y: ]) y
by other systems. It is not self-producing.<br/>' X1 d# F: P; q! N+ y% z
At first sight this may seem an almost trivial idea, yet further contemplation reviews how significance it is. For example:<br/>5 ~! I- J' M$ J% k/ ?* m
1. Imagine try to build autopoietic machine. Save for energy and some* S# r7 z' c4 L% Q, {3 D) O
basic chemicals, everything within it would itself have to be produced
+ r' ?. T4 D4 `* l. R- w$ |& a* G4 `by the machine itself. So, there would have to be machines to produce
% D3 t5 j- P* ]: u2 a. h, f/ Gthe various components. Of course, these machines themselves would have
" l! Y, N# P" r- h' k) gto be produced, maintained, and repaired by yet more machines, and so
- m8 k0 r) I' o; |on, all within the same single entity. The machine would soon encompass
* k2 S; I) e" Q8 z. p% n' Athe whole economy.<br/>
( S: j/ e5 s2 X2. Suppose that you succeed. Then surely what you have created would be
" W; Q0 e, m$ S- L! Cautonomous and independent. It would have the ability to construct and
% y& {: {8 e# K$ dreconstruct itself, and would, in a very real sense, be no longer' w& g; u( d. Y; c8 o) U/ D
controlled by us, its creators. Would it not seem appropriate to call
5 L2 X4 S9 E: K4 e, R' Bit living?<br/>. t5 ^, t6 K/ v! C, Y. N
3. As life on earth originated from a sea of chemicals, a cell in which$ ~& M/ }/ Z# f# g4 ^8 K1 l1 r
a set of chemicals interacted such that the cell created and re-created
" `1 {7 f7 v6 q3 `2 U( ~4 [its own constituents would generate a stable, self-defined entity with3 `( d$ O& D5 l( ?% S2 t( D7 \: u
a vastly enhanced chance of future development. This indeed is the5 L& _5 b5 a U
basis for current research, to be described in section 2.4.1<br/>
+ ]/ Y; ^! D5 g' _- P2 b4. What of death? If, for some reason, either internal or external, any
! }8 y% a+ j0 W9 s& Ipart of the self-production process breaks down, then there is nothing
6 \$ i1 G4 D, j/ W" y2 jelse to produce the necessary components and the whole process falls
2 B9 T+ Q- q& e% M) p7 d' f+ s8 u9 n' ~apart. Autopoiesis is all or nothing – all the processes must be
( |6 n* Q5 Y$ a9 {, o1 X5 Oworking, or the systems disintegrates.<br/>) S% J; ]; B' E( z
This, then, is the central idea of autopoiesis: a living system is one
" z) L; q* u% ~) ?organized in such a way that all its components and processes jointly
1 Q% v8 ?- Z) Rproduce those self-producing entity. This concept has nearly been7 X$ Z- e3 \, ~
grasped by other biologists, as the quotation from Rose at the start of
8 ]+ }7 g9 `$ F. f( z. T9 W" }8 dthis chapter shows. But Maturana and Varela were the first to coin a
$ n1 J2 k9 C V0 V/ [; I9 [4 {word for this life-generating mechanism, to set out criteria for it
1 P3 ~1 J1 ~2 g5 ?! f% d9 ](Varela et al., 1974), and to explore its consequences in a rigorous& p+ \# }6 y: g# r* C; U, _
way.<br/>
, g& D; w& B! l* B: \$ l: U U) vConsidering the derivation of the word itself, Maturana explains that, f$ @- D+ W7 z4 |' h5 L
he had the main idea of a circular, self-referring organization without7 q+ X7 w7 ` g2 N8 z( {
the term autopoiesis. In fact, biology of cognition, the first major
0 ]+ K1 J( F! }; dexposition of the idea, does not use it. Maturana coined the term in
) t( L3 M# A& ]- [+ jrelation to the distinction between praxis (the path of arms, or7 J! S& f$ @+ }3 w( t
action) and poiesis (the path of letters, or creation). However, it is
) d" S2 W" G1 w c: d8 ]& p Yinteresting to see how closely Maturana’s usage of auto- and
$ G; i3 N% }) F4 M: }! P/ \allopoiesis is actually foreshadowed by the German phenomenological; G6 ^& G' A# m @2 L6 T$ d
philosopher Martin Heidegger. In the quotation at the start of Chapter
/ [8 t6 u- k) X [7 C' d& I1, Heidegger uses the term poiesis as a bringing-forth and draws the
! e7 X0 N1 ]; N8 Y4 ^contrast between the self-production (heautoi) of nature and the: D. v1 w- r2 ~" V q
other-production (alloi) that humans do. Heidegger’s relevance to& r1 R Z9 U; [
Maturana’s work will be considered further in Section 7.5.2<br/>
- W. F+ ^' H, B5 S2.2 Formal Specification of Autopoiesis<br/>, @2 b& B8 r9 o+ _7 Z' ~- D( u
Now that I have sketched the idea in general terms, this section will
4 {$ \6 \( F& j! a f: U$ fdescribe in more detail Maturana’s and Varela’s specification and
4 T5 y! z% H9 D) ovocabulary.<br/>- W* [. A. D: V# m" A
We begin from the observation that all descriptions and explanations
. @( a- y8 ~8 F7 Mare made by observers who distinguish an entity or phenomenon from the
6 [/ J( b6 s, z$ ~" Igeneral background. Such descriptions always depend in part on the
; U. |' X" o& A9 ?choices and processes of the observer and may or may not correspond to
7 N! z$ V# w1 j3 \" N( |( g# Bthe actual domain of the observed entity. That which is distinguished+ l7 J9 x. s4 C; }+ k6 I1 d. S$ u" T
by an observer, Maturana calls a unity, that is, a whole distinguished
* ~. Y. h) x" D9 U* r& Bfrom a background. In making the distinction, the properties which
1 `3 J5 p( R C3 S1 B( wspecify the unity as a whole are established by the observer. For" ]% m1 F" a% V$ a* h# d
example, in calling something “a car,” certain basic attributes or
. F: }, V9 ?0 N F7 m! K) Pdefining features (it is mobile, carries people, is steerable) are
4 V6 p5 z7 I2 A7 Rspecified. An observer may go further and analyze a unity into
$ X2 K$ t" g) F2 F g3 ccomponents and their relations. There are different, equally valid,' G/ @3 \5 T4 D7 R' A9 H
ways in which this can be done. The result will be a description of a0 n" Z& T) x* t0 J2 |' ~: x
composite unity of components and the organization which combines its) X! p8 C$ ^0 ?2 f2 }& ?7 l% N8 c
components together into a whole.<br/>2 o; Q4 @/ j6 ~5 E; c! a( ?, R" l2 X
Maturana and Varela draw an important distinction between the organization of a unity and its structure:<br/>2 e- _, |4 f6 T: g$ y4 L7 ?
[Organization]refers to the relations between components that define
, }$ a: H" e$ e" ~: M8 z+ pand specify a system as a composite unity of a particular class, and( n% A: p! t; S2 y$ v
determine its properties as such a unity … by specifying a domain in5 J8 J/ i* {% A1 E3 h* c0 E+ d
which it can interact as an unanalyzable whole endowed with
- K8 E9 X1 ^2 X' O8 N: G$ tconstitutive properties.<br/>
% ]3 n" m) e" n0 y[Structure] refers to the actual components and the actual relations
: K3 Y+ g' O, Q: C2 J% w8 g1 @4 Zthat these must satisfy in their participation in the constitution of a, d: [1 F S! y P1 j0 s
given composite unity [and] determines the space in which it exists as
( N7 n3 U5 \2 ca composite unity that can be perturbed through the interactions of its
5 N9 Y$ H3 {9 G- ]) G" Hcomponents, but the structure does not determine its properties as a
' C+ @6 C' d U/ Kunity.<br/>
) Q! Y! j& b; ~+ w4 N/ u- `& t# qMaturana (1978, p. 32)<br/>+ b( R; j- B6 q8 }0 n
The organization consists of the relations among components and the
: q( p }/ U1 H. ?# snecessary properties of the components that characterize or define the
/ Y8 B' a7 M7 \6 `6 ?unity in general as belonging to a particular type or class. This
# f5 `2 l$ F; J/ C7 c: Q$ k! A cdetermines its properties as a whole. At its most simple, we can2 Q9 F3 q: c- m, _# |
illustrate this distinction with the concept of a square. A square is
. ~% j1 B4 M# qdefined in terms of the (spatial) relations between components – a
) N. {0 K0 u& V) Ofigure with four equal sides, connected together at right angles. This& j9 G% f& j+ K3 ~# B" A- \
is its organization. Any particular physically existing square is a
2 M/ ~" s' n* f2 u2 Oparticular structure that embodies these relations. Another example is" {3 P2 M# W5 J% K: o" o) `7 ^
a an airplane, which may be defined by describing necessary components
4 D( ]" ]1 v9 u- S% Bsuch as wings, engines, controls, brakes, seating, and the relations
5 R9 `& z v0 Y5 Abetween them allowing it to fly. If a unity has such an organization," V* [9 f! m1 L5 Q
then it may be identified as a plane since this particular organizatio
. i& o7 q) k2 Z9 Q/ Zwould produce the properties we expect in a plane as a whole.
. T. }! F. J8 a0 _Structure, on the other hand, describes the actual components and
( N9 x9 [8 u: G6 M, s& R, F, N1 Wactual relations of a particular real example of any such entity, such" |1 D0 ?) y* f# I! f
as the Boeing 757 I board at the airport.<br/># ^1 T* U) P4 C! e: o
This is a rather unusual use of the term structure (Andrew, 1979).
7 W* p1 ]. W6 E1 U S2 w( tGenerally, in the description of a system, structure is contrasted with
' S! c9 \7 {5 h# I( Z8 kprocess to refer to those parts of the system which change only slowly;% u0 y V& ^7 \: [$ m6 k
structure and organization would be almost interchangeable. Here,
0 n8 T/ l0 F' u+ b+ D# h7 M4 b9 yhowever, structure refers to both the static and dynamic elements. The* w. I0 K" \% |4 V* t
distinction between structure and organization is between the reality
" \ d) u- a# V% a$ {of an actual example and the abstract generality lying behind all such2 j+ Y% O; k" q
examples. This is strongly reminiscent of the philosophy of classic
* [% z' x/ W& z1 H8 ?% H; k5 ostructuralism in which an empirical surface “structure” of events is
" K2 g5 C `/ ~' y1 X+ T: rrelated to an unobservable deep structure (“organization”) of basic
0 H* @9 u0 A6 ~8 Hrelationships which generate the surface.<br/>
) R) U7 ^. T6 D, r. rAn existing, composite unity, therefore, has both a structure and an$ J7 i$ g: r- H' B: q/ B7 a2 m0 s& n
organization. There are many different structures that can realize the
' m0 V! K8 F, j& [8 Wsame organization, and the structure will have many properties and- K: f/ |3 H. p1 L
relations not specified by the organization and essentially irrelevant* ~, T: M# W' O
to it – for example, the shape, color, size, and material of a
: _# S/ \+ C2 K6 g7 `particular airplane. Moreover, the structure can change or be changed
% j& {5 E9 E: y* m" Z. Wwithout necessarily altering the organization. For example, as the& u; A' Q/ S0 i8 k
plane ages, has new parts installed, and gets repainted it still
0 @+ R' m! `8 W* |# t; w5 C$ emaintains its identity as a plane because its underlying organization. d8 r& u, B1 y# m, U
has not changed. Some changes, however, will not be compatible with the7 C# ?3 C- |. b% v) n3 f8 t5 q
maintenance of the organization – for example, a crash which converts5 ]$ @: `3 H- n! Q$ f
the plane into a wreck.<br/>
* a. T5 V. Y. f# oThe essential distinction between organization and structure is between R5 m8 g3 R( R" |
a whole and its parts. Only the plane as a whole can fly – this is its' h8 G! G( T! }0 _0 E$ W1 v
constitutive property as a unity, its organization. Its parts, however,0 t. V B. Y1 C0 Y2 K N; b# Y
can interact in their own domains depending on all their properties, i2 ]* ^$ `0 z
but they do so only as individual components. Sucking in a bird can
5 M9 i ]4 c# X8 Kstop an engine; a short circuit can damage the controls. These are
- i i+ L9 L2 g2 c! z* Mperturbations of the structure, which may affect the whole and lead to
% s5 O) D8 p/ f9 D) Ba loss of organization or which may be compensable, in which can the( Y) Z4 `0 f6 f( p) x
plane is still able to fly.<br/>
8 D& q' d" \- KWith this background, we can consider Maturana’s and Varela’s
7 g4 U; T8 Q8 _; o5 K2 S& x3 ~definition of autopoiesis. A unity is characterized by describing the8 T$ V N' Z3 M( A9 q C
organization that defines the unity as a member of a particular class8 \: M# t$ Q9 d% W! o
that is, which can be seen to generate the observed behavior of unities
5 L6 Z8 b$ e9 {3 X& D/ Kof that type. Maturana and Varela see living systems as being- L$ y, ^# F9 a2 ~( S, s& h4 L
essentially characterized as dynamic and autonomous and hold that it is
. [6 }6 G1 Q( Z; Y6 Ptheir self-production which leads to these qualities. Thus the
n" @" J5 H$ _( forganization of living systems is one of self-production – autopoiesis.
+ }/ [- d0 a8 I' q" n* J1 n/ pSuch an organization can, of course, be realized in infinitely many4 Y. M& ] |# V6 u& S; ~
structures.<br/>
5 I) j, e1 c% o+ C0 t7 E/ O+ pA more explicit definition of an autopoietic system is<br/>3 N, Q) A3 U# N* S/ t
A dynamic system that is defined as a composite unity as a network of productions of components that,<br/>
' V& |$ V% }2 j4 Oa) through their interactions recursively regenerate the network of productions that produced them, and <br/>
" f0 J! g& ~" ^( Z7 N7 `b) realize this network as a unity in the space in which they exist by" K; {( o8 b; g" c+ e I+ h
constituting and specifying its boundaries as surfaces of cleavage from
( K+ t' @4 h7 o( }2 ~% z) Vthe background through their preferential interactions within the
; w9 n3 C7 H! xnetwork, is an autopoietic system. Maturana (1980b, p. 29)<br/>1 E+ u4 \+ m& @' ?) L
The first part of this quotation details the general idea of a system
4 o7 @5 x3 p& ^# @4 Uof self-production, while the second specifies that the system must be
8 ^8 [/ \$ V8 b, s/ ~. [actually realized in an entity that produces its own boundaries. This; G5 A M) m S& z! K, E" z
latter point, about producing boundaries, is particularly important0 L' L3 r: p' D
when one attempts to apply autopoiesis to other domains, such as the [' x) W5 Q5 Y) J0 R6 w+ h7 V
social world, and is a recurring point of debate. Notice also that the
. Z9 ~7 V c& odefinition does not specify that the realization must be a physical* p' g. k- }* C
one, although in the case of a cell it clearly is. This leaves open the
8 S/ v" G" D& r f( Ridea of some abstract autopoietic systems such as a set of concepts, a
4 }9 ]: R( r6 h ?/ l3 S# lcellular automaton, or a process of communication. What might the
; p v; z- K2 V7 O/ ?* g/ _& e4 q4 }boundaries of such a system be? And would we really want to call such a
3 `8 M5 A& }% J) n! E9 ~system “living”? Again, this is the subject of much debate – See' Q& V. o( o t% E5 p0 Q7 V
section 3.3.2<br/>
; I. L3 }% ^! t" p% x* G( aThis somewhat bare concept is further developed by considering the
( w, i5 M- {, k& Fnature of such an organization. In particular, as an organization it- Q( Z+ M5 x+ {; U# | g( j( Y& E
will involve particular relations among components. These relations, in
6 f9 N5 O( _1 s: M0 j P9 A- uthe case of a physical system, must be of three types according to3 J) R. W6 |; u+ \
Maturana and Varela (1973): constitution, specification, and order.# c6 s0 N: [; D5 |+ r
Relations of constitution concern the physical topology of the system4 ]" I b4 y. G+ B. M1 w8 V
(say, a cell) – its three-dimensional geometry. For example, that it' g, D, o( l8 F- E/ j$ W/ T& b
has a cell membrane, that components are particular distances from each
% n& q; e. s! @+ c: e bother, that they are the required sizes and shapes. Relations of6 J' u/ N8 {: A6 H+ \. H
specification determine that the components produced by the various' B$ S7 V) S' b- a4 n
production processes are in fact the specific ones necessary for the
& f" M$ v( f8 t4 ^5 Kcontinuation of autopoiesis. Finally, relations of order concern the
0 E3 s" b# {6 |* K* z6 Z% wdynamics of the processes – for example, that the appropriate amounts
# m7 d( i& C$ A' d m5 f( Qof various molecules are produced at the correct rate and at the# P/ m1 X. ^; I4 Q8 E" _
correct time. Specific examples of these relations will be given later,: f# J G/ G- P# ]
but it can be seen that these correspond roughly to specifying the
+ C4 g( {% Z: Y3 V( ^“where”,”what”, and “when” of the complex production processes! c3 P, E+ a m7 l1 `
occurring in the cell.<br/>
4 `& w* z( w$ \0 A% W- A+ [It might appear that this description of relations “necessary” for
# V$ M @: T6 r- w1 Z& M- hautopoiesis has a functionalist, teleological tone. This is not really
[/ i3 U6 l6 s/ \8 g2 J+ {$ }9 nthe case, as Maturana and Varela strongly object to such explanations.$ G. z5 w: y/ V& g- W1 M
It is simply that, if such components and relationships do occur, they& `; u( w/ D) T2 M# H$ X
give rise to electrochemical processes that themselves produce further
8 Z) p) h3 @* A0 tcomponents and processes of the right types and at the right rates to
+ i! Q' h5 K" \3 f! V' lgenerate an autopoietic system. But there is no necessity to this; it: @8 c( {& L# C9 o5 {$ i( d
is simply a combination that does, or does not, occur, just as a plant+ F" N+ x% u {5 I7 U: r4 S% b; x7 ^2 H7 R
may, or may not, grow depending on the combination of water, light, and
+ E; ?9 ?' g# J T, nnutrients.<br/>
- G2 h- S0 |* J* FIn an early attempt to make this abstract characterization more
% V0 w, p. C- Loperational, a computer model of an autopoietic cellular automaton was
8 s" z1 s. I+ pdeveloped together with a six-point key for identifying an autopoitic
% Y/ d+ g" }. Ksystem (Varela et al., 1974). The key is specified as follows:<br/>
+ a ^" J, S& d- V: \ c- [i) Determine, through interactions, if the unity has identifiable
$ g" x! B: m" C, H. D& X% jboundaries. If the boundaries can be determined, proceed to 2. If not,
( y, U& y4 m2 Z$ ^+ _the entity is indescribable and we can say nothing.<br/>, F4 Q9 A0 q- D
ii) Determine if ther are constitutive elements of the unity, that is,# u+ W4 }' ^4 k8 d+ i! }4 O
components of the unity. If these components can be described, proceed
0 ?. v! \$ A3 e. Y) lto 3. If not, the unity is an unanalyzable whole and therefore not an
# O |: V8 F0 V; E- `0 Iautopoietic system.<br/>5 n |4 u* X7 }0 e
iii) Determine if the unity is a mechanistic system, that is, the
7 B2 x! ?5 n8 m5 Ccomponent properties are capable of satisfying certain relations that
. h6 j- m G0 \determine in the unity the interactions and transformations of these# ?* M% \6 K6 W+ F* O! L0 M
components. If this is the case, proceed to 4. If not, the unity is not
( _3 r$ s ?& Dan autopoietic system.<br/>$ M, t+ m6 u& n9 V
iv) Determine if the components that constitute the boundaries of the* ~8 U6 l6 R2 r
unity constitute these boundaries through preferential neighborhood. J. ]/ ? n4 ^$ {1 ]9 L" M
interactions and relations between themselves, as determined by their
/ W* y5 r9 |6 D) ]properties in the space of their interactions. If this is not the case,
' ]) ?# M: ?1 p# x8 C3 P0 @* j! O& M6 {you do not have an autopoietic unity because you are determining its/ _! l0 g6 A- W* L1 ^$ g
boundaries, not the unity itself. If 4 is the case, however, proceed to+ |9 x7 g7 o9 B. G N
5.<br/>
. z" K" \$ _1 m! r: dv) Determine if the components of the boundaries of the unity are
! n; }( u/ b" G! Q+ ]" r2 w# fproduced by the interactions of the components of the unity, either by2 H! n, S% Y% l8 u2 Q& K4 j) c8 Y
transformation of previously produced components, or by transformations
4 b2 ?1 g, j7 K9 d" b+ Z, n2 Jand/or coupling of non-component elements that enter the unity trough
, M/ Z9 Q$ K. r3 u6 j7 xits boundaries. If not, you do not have an autopoietic unity; if yes2 n7 [2 k7 |- e9 Q, E
proceed to 6.<br/>6 ~0 C9 |( p/ ], `7 J
vi) If all the other components of the unity are also produced by the- I! `$ T! b' b/ D1 l6 K l
interactions of its components as in 5, and if those which are not! w" }. h. y% S" R, S! h8 D
produced by the interactions of other components participate as
0 ^, n" r3 M# J9 q2 hnecessary permanent constitutive components in the production of other
7 O! `& O7 g9 c# h" ~5 qcomponents, you have an autopoietic unity in the space in which its) p9 l( y2 F* U' T2 [& N/ Z
components exist. If this is not the case, and there are components in! v) v9 s6 e) t* l. G7 n
the unity not produced by components of the unity as in 5, or if there
3 W+ P' o+ n) ]7 z6 eare components of the unity which do not participate in the production
$ y# `' j9 x; B* O B A+ l! ?" |of other components, you do not have an autopoietic unity.<br/>) k& S4 T9 o# g% o& J1 X+ Y3 g( I
The first three criteria are general, specifying that there is an
. b6 L2 A+ j$ yidentifiable entity with a clear boundary, that it can be analyzed into- s' Z, l! I% ^# S" [9 V1 |
components, and that it operates mechanistically, i.e., its operation
' |- Q5 |. q! W! y6 Z7 ~is determined by the properties and relations of its components. The3 i% A2 n5 R3 A# ?) G6 C
core autopoietic ideas are specified in the last three points. These- k7 `/ O" v. N7 \2 Q) N) Y
describe a dynamic network of interacting processes of production (vi),/ _9 V% ?3 w/ [1 P0 N7 i
contained within and producing a boundary (v) that is maintained by the
& _" ]+ I+ ]6 C. A( wpreferential interactions of components. The key notions, especially
9 ^0 B! J$ r' Kwhen considering the extension of autopoiesis to nonphysical systems,
5 d( T; p Y# P; T$ a9 Gare the idea of production of components, and the necessity for a
6 o/ I1 S* H- L, |& Kboundary constituted by produced components.<br/>
3 f) F2 L4 w& R SThese key criteria will be applied to the cell in the next section.( W4 G+ `: V1 b7 G3 C' f7 K* F! {
This section will describe briefly embodiments of the autopoietic- C; a( ~) d4 v5 i1 n; S
relations outlined above in the chemistry of the cell. Alberts et al.
1 v X* r) W% [or Freifelder are good introductions to molecular biology, as is Raven- a; w( K$ X& M% ~1 z( O2 C+ C
and Johnson to the cell.<br/>6 D F6 d/ \1 S3 a7 @/ D2 F
2.3 An illustration of Autopoiesis in the Cell<br/>
" u9 T7 m7 p& z1 F7 l! \# b" JThis section will describe briefly embodiments of the autopoietic
' |) I( F% @* frelations outlined above in the chemistry of the cell. Alberts et al.) U4 ?6 @; x& {* p4 W9 R' X
are good introductions to molecular biology, as is Raven and Johnson to0 I! [: m0 _# _9 l: d/ V
the cell.<br/>, A7 G" _. T) S* C1 U, b) }+ {, S6 H4 r
2.3.1 Applying the Six Criteria<br/>
: s7 E: V! z6 _Zeleny and Hufford analyze a typical cell with the six key points. A4 \$ i0 T0 ]1 l, h `$ u
schematic of two typical cells is shown in Fig 2. One is a eukaryotic
* Z) y& A) {: A4 I- \cell, i.e., one that has a nucleus, and the other is a prokaryotic7 c4 A3 ^+ }8 q4 P0 J
cell, which does not.<br/># T, W8 N+ U" T- n2 S- G7 h
1. The cell has an identifiable boundary formed by the plasma membrane. Thus, the cell is identifiable.<br/>
" I w g+ Z4 }& J2.The cell has identifiable components such as the mitochondria, the
8 z3 Y1 { p8 C7 N% ~+ L1 S0 I0 J- xnucleus, and the membranous network known as the endoplasmic reticulum.
" }" ^2 n. K; ]" LThus, the cell is analyzable.<br/># Q/ [# B5 G) m5 d
3. The components have electrochemical properties that follow general
4 P6 Y: z; F! p5 U3 Mphysical laws determining the transformations and interactions that) A( u9 i ^8 C% q8 ` A6 ^
occur within the cell. Thus, the cell is a mechanistic system.<br/>
1 H' T* N0 i0 f4.The boundary of the cell is formed by a plasma membrane consisting of
e) w f" U/ w9 a" ^! J" |- ?phospholipids molecules and certain proteins (fig 3). The lipid" }# u) o( A. y3 _
molecules are aligned in a double layer, forming a selectively
( V+ b7 F- S6 `# X {permeable barrier; the proteins are wedged in this bilayer, mediating2 g; q7 n+ h0 @7 G/ T# l. s5 R
many of the membrane functions. A lipid molecule consists of two parts
x1 ^, {9 V4 x% D8 k– a polar head, which is attracted to water, and a hydrocarbon (fatty)
' |- g; `0 X+ J2 A$ Ptail, which is repelled. In solution, the tails join together to form
8 y( _5 D1 H/ ?! n0 bthe two layers with the heads outside. The integral proteins also have
4 G; A! v& P, ?areas that seek or avoid water. The boundary is therefore& O0 H E1 D( r6 T
self-maintained through preferential neighborhood relations.<br/> F( a5 {9 B( a7 D/ Q! k. M
5. The lipid and protein components of the boundary are themselves
$ Y/ w) U/ _ N$ R( w0 Qproduced by the cell. For example, most of the lipid molecules required. x* R. u, G# Y! q9 [( g6 F
for new membrane formation are produced by the endoplasmic reticulum,2 B$ W$ w9 f( s
which is itself a complex, membranous component of the cell. The
. N4 ^# V( D6 S; ]' C( I2 j8 j: u6 s( oboundary components are thus self-produced.<br/>
# i' O y% u, a$ m8 B+ \) c. b- @6. All of the other components of the cell (e.g., the mitochondria, the( i+ p0 g% M- G
nucleus, the ribosomes, the endoplasimic reticulum) are also produced8 j* ?: i% S n# h; k- `# K
by and within the cell. Certain chemicals (such as metal ions) not1 t" `0 i# `( t1 Y
produced by the cell are imported through the membrane and then become
6 g& a0 ~' F9 v3 k. bpart of the operations of the cell. Cell components are thus( A1 z- `$ l: J) E
self-produced.<br/>' z& r, ~% a8 v k
2.3.2 Autopoietic Relations of Constitution, Specification, and Order<br/>% d" \9 h9 e. o( j& N" k
Apart from the six-point key, autopoiesis was also defined by three
2 t0 O; D& Q, t- k' Q onecessary types of relations. These can be illustrated as follows for a5 S) U1 D9 q- f1 P4 [9 M
typical cell.<br/>* s1 X* z7 H" a! M- m2 F1 h* F M0 o
2.3.2.1 Relations of Constitution<br/>8 d! ~0 h8 a. Y
Relations of constitution determine the three-dimensional shape and
; q, O2 Z0 ~9 B3 n" Tstructure of the cell so as to enable the other relations of production
! x6 P, K$ t, i% J; Eto be maintained. This occurs through the production of molecules
) \- b: `6 q3 n& Fwhich, through their particular stereochemical properties, enable other
8 D8 ?: _6 X. i, v$ ^6 lprocesses to continue.<br/>( P1 ], J6 b) Q' B* j
An obvious example is the construction of membranes or cell boundaries.9 I5 [4 S5 S" K7 x7 }" ?# a& I
In animal cells, the membrane surrounding the mitochondria, like that
1 N4 S' G4 Q4 J- G/ X0 Taround the cell itself, serves to harbor cell contents and control the
/ Z- k+ G% O# q/ ~8 n$ q j* xrate of reaction through diffusion. Various reactive molecules are) ^8 {: R5 V. N2 b$ l& w$ c3 a+ K
distributed along the inner membrane in an appropriate order to allow a" m8 \0 x% c% s! O' p
energy-producing sequences to proceed efficiently. In plant cells, in
8 u0 W; ]) e4 p: k( @1 c7 Saddition to the plasma membrane, there is a cell wall, which consists% I+ u" K+ I+ e) D
of cellulose, a material made up of long, straight chains of glucose
$ T$ @! E8 M9 D4 r: V( O& sunits packed together to form strong rigid threads. These give plants. s7 Q$ c1 X2 L6 u, C
their rigidity.<br/>/ {* A4 }3 e, L1 ^
A second example is the active sites on enzymatic proteins. These act! S0 c, w5 E. c% u% t$ v, p+ d
as catalysts for most reactions, changing a particular substrate in an
' q4 k- P# d0 W/ s0 g& c7 p8 xappropriate way to allow it to react more easily. Generally, the active$ N+ k T( r3 F
site is found in certain specific parts of the enzyme molecule where2 I# e" o5 A$ A/ J0 O
the configuration of amino acids is structured to fit the particular
6 c6 E, b) Q- K5 esubstrate, sometimes with the help of “activators” or co-enzymes. The
/ `: d$ E( _" K) N" E0 isubstrate molecule interlocks with the active site and in so doing
5 \& Q5 [9 w7 Q4 J' Y3 Jchanges appropriately so that it no longer fits, and thus frees itself.<br/>
, Q& Q% ]" C: F' p4 u2.3.2.2 Relations of Specification<br/>
" w% G; e! l2 }$ ?$ cThese determine the identity, in chemical properties, of the components F& V, }& Z- @, P- i
of the cell in such a way that through their interactions they# |8 t( v: v' _$ ~
participate in the production of the cell. There are two main types of4 Y$ J2 ~, Y6 q# b( |1 q
structural correspondence, that among DNA, RNA, and the proteins they7 N; g: O+ c% ~( I8 P
produce and that between enzymes and the substrates they catalyze.<br/>2 I7 W9 Z/ Q: ?2 ~6 R3 v. V
Protein synthesis is particularly complex because each protein is. C& E* Z6 [0 W- x) N1 i6 n
formed by linking up to twenty different amino acids in a specific
1 Z- F( q: P6 m9 m: U8 tcombination, often containing 300 or more units in all. This requires
; ?( C% Q5 G' v1 u; E3 V2 C qan RNA template molecule, tailor-made for each protein, containing6 b ]! U" j# G( l
specific spaces for each of the amino acids in order, together with an+ T: F( q. y: R/ d
enzyme and t-RNA for each acid.<br/>
3 F3 S- }% H# m9 R. \As already mentioned, enzymes are necessary to help most of the4 D5 V, }) |; q
reactions in the cell, and again, each specific reaction requires an
7 Y/ _( s Y) S5 Y: R- kenzyme specific to the reaction and to the substrate involved. Hundreds2 C9 |8 Q$ ~" W9 t R. q
of such enzymes are needed, and all must be produced by the cell.<br/>
9 B6 {9 S! x2 t( R. H$ B: x2.3.2.3 Relations of Order<br/>4 r/ M8 {$ j0 h: q8 Q( c
Relations of order concern the dynamics of the cell’s production
( W/ R8 s+ @, M6 F- g1 iprocesses. Various chemicals and complex feedback loops ensure that# Z- M1 ]+ P! T: H
both the rate and the sequence of the various production processes3 k( B2 [5 a0 t- m+ ?9 Q" a
continue autopoiesis. For instance, the production of energy through
S( x- ]' c9 A( N: J; y) z0 Q6 noxidation is controlled by the amount of phosphate and ADP (adenosine
( E- Z; v8 u# j1 I% X4 O6 Vdiphosphate) in the mitochondria. At the same time, reactions that use
8 c$ F$ P9 B7 Fenergy actually produce ADP and phosphate so that, automatically, a
/ w8 q$ b. ~8 Z+ Y) x5 P0 Jhigh usage of energy leads to a high production rate of these necessary6 r0 A$ }5 Y4 A: T7 a7 Q) _8 A
substances.<br/>
+ Y: ?# X: Y/ @& Z0 [/ {* M2.3.3 Other Possible Autopoietic Systems<br/>/ C1 E6 @. p1 m' _
An interesting question leading from the idea of the cell as an) X2 f4 s/ ?$ s, l: Y2 Q; K1 n
autopoietic system is whether or not there are other instances of
r) w. ?0 N/ c# d7 ?) |+ p2 {autopoietic systems. Are multicellular organisms also autopoietic) P/ o- A( Q: E: G( Z9 b
systems? Maturana is equivocal, suggesting that organisms such as& g- ^9 Z& ~' e: B
animals and plants may be second-order autopoietic systems, with the
' F% |, h8 ^/ b# ~/ Q% zcomponents being not the cells themselves but various molecules; u5 b* ]% m* ^ j' W$ X
produced by the cells. On the other hand, he suggests that some8 q! s- }7 f5 r( I+ m1 U% \9 O
cellular systems may not actually constitute autopoietic systems, but2 R b1 [. c6 n$ A
may be merely colonies. What about a system that appears to have a5 E4 p- j4 h% @0 v
closed and circular organization but is not generally classified as
& \$ @1 ~. _8 R: ^2 ^& G* uliving, such as the pilot light of a gas boiler? Finally, what about
# q* c" P- Z& h2 R& u$ inonphysical systems such as the autopoietic automata mentioned in& z: h$ Y) D3 B* i' ]
section 2.2.1 and described more fully in section 4.4, or systems such9 V, N. p$ V: Z& i
as a set of ideas or a society? These possibilities will be discussed& o7 s7 T- a+ o3 s
in more detail in Section 3.3.<br/>
h* u# A; T, k% L2.4.Applications of Autopoiesis in Biology and Chemistry<br/>* f2 d* h" _3 M: }0 k: k
One would have expected that, given the importance and nature of its
* m2 I: t8 O4 y' ~claims, autopoiesis would have had a major impact on the field of8 \3 u; r3 D; P2 F7 s O- o
biology. In fact, for many years there was a noticeable reluctance to
- D, s7 g3 n" l3 F0 l% Etake the ideas seriously at all. In 1979, I wrote to an eminent British
1 n0 Q' e1 k% {* h% a' ibiologist – Professor Steven Rose at the Open University – querying the: P/ _# S# E+ r1 z
status of autopoiesis. He replied to the effect that he did not wish to* U0 l& K" x$ |0 ?& ^+ Z: |& c
comment on autopoiesis but that Maturana was a reputable biologist. One) C! r4 ]- ~: ^6 a% x& l
notable exception is Lynn Margulis, whose own theory, that eukaryotic
- g9 m* q+ A [# [cells evolved through the symbiosis of simpler units, is itself quite
! W& Q2 _$ n& Y1 K1 ]controversial.<br/>
9 m. G: W8 x3 O3 DHowever, recently interest has been growing in two areas: research into! T( A9 x O' }9 i V. ~" M3 ]
the origins of life and the creation of chemical systems that, although- E) h% Y. [5 B6 N% K" o) |
not living, display some of the characteristics of autopoietic& i1 R1 s' C2 S1 O N! I
self-production. Autopoiesis has also been compared with Prigogine’s
( c6 L2 r, y% |4 }- pdissipative structures. Varela has also pursued work on the nature of' |0 q- i6 ]" g, i* M
the immune system, viewing it as organizationally closed but not4 H) G# E# {% l
autopoietic. However, as this topic is very technical and not of
) ^2 D8 b' d/ Dprimary relevance, it cannot be pursued here.<br/>
1 W( a! K/ m" J& a! f0 C' ^2.4.1 Minimal Cells and the Origin of Life<br/>
1 v# t u# ?9 eThere are two main lines of approach to theories concerning the origin6 X- E0 v3 l1 Y' ~3 a. @
of life on Earth. In the first approach, based on study of the enzymes
/ [& q# g# | P% ^7 M% R6 P7 a/ _7 {and genes, life is characterized as being molecular and a defining
' K. r% e" [% d2 u& \* \3 hfeature is the structure and function of the genes. In the second7 M8 Z+ T4 @5 R& n5 j9 q! P1 w
approach, life is characterized as cellular, and its defining feature/ }' u2 d' u- S3 s/ t! ?% \6 x
is metabolic functioning within the cell. However, neither approach can
2 G9 [2 h' H0 I7 y% \2 Freally specify a standard or model for life against which important' X2 _# K+ B/ O1 M" \( F. A4 a7 r
questions may be answered. In particular, at what point did prebiotic
# \& O, G3 \( I! a) Kchemical systems become biotic living systems? And how could we
; O) T+ W8 a8 P$ F" I# |recognize nonterrestrial living systems. Which might be radically
3 d5 E4 C6 c5 ?6 ^8 g+ edifferent in structure from our own?<br/>+ u: _* a4 H; g9 ]& x6 \
Fleischaker proposes that the concept of autopoiesis, together with K4 q( u& t5 D# }9 @8 `* X, H
notions of minimal cell, can provide a sound theoretical framework to% A: J/ _6 ~) u3 D9 W
tackle these questions within the second tradition mentioned above.& F2 Q, p. l, t( C) l
Autopoiesis clearly does aim to provide a specific and operationally
- R; C; f J. b& tuseful definition of life, although Fleischaker argues that the concept* `, B" S# w S2 p! U( z$ F
of autopoiesis does need some modification. This modification would. u. g S) I) \# c- ]) h- {* ~
restrict “living” systems to autopoietic system in the physical domain/ ]0 ]% @4 X/ ~ r0 \
rather that allow the possibility of nonphysical living systems, a
7 f4 p2 ~0 h" }; m$ L# e% n) V2 J( Wpossibility which ( as mentioned above) is left open by the formal* H$ ^# [) q2 T. z) G# D& S
definition of autopoiesis. This will be discussed in Section 3.3.2<br/>
, j) y: f8 K ?4 G+ PGiven autopoiesis (or modified version) as a definition of life, the/ n8 |' z& p( U+ s
next step in theorizing about the origin of life is to consider how an. ?' o8 y+ F/ R7 W3 N
elementary autopoietic system might have formed. Note that autopoiesis @; [% u4 Z1 n m5 H; {: S3 Z
is all or nothing. A self-producing system either exists and produces
8 O; A" P+ F5 u2 Fitself or it does not – there can be no halfway stage. This leads to" d6 Q) m# H: J5 F2 |" @' c9 g
the idea of a theoretical “minimal” cell which could plausibly emerge,+ I$ S4 O2 ^2 l# p# K; X
given the early conditions on earth. In fact, Fleischaker considers
/ q& O, Z+ ]8 q" z3 Z& D5 }# Sthree different characterizations of minimal cells: a minimal cell
! F- g- W) I3 B! F6 |* prepresentative of the evolved life forms that we know today; a minimal
; u3 I% k, s+ acell that would characterize both terrestrial and nonterrestrial life
% f. H% R& u6 u0 b3 q" Xregardless of its constituents.<br/>+ f! H/ y. x0 ?7 z' ^3 }& y8 e% Z3 t
About the last, little can be put forward beyond the six-point. t1 C: j+ S7 V
autopoietic characteristics in the physical space; to be more specific
% D7 v, b" g7 R' I' J' Y# ewould constrain the possibilities unnecessarily. On the other hand, we
$ ]. r/ `; I, ccan be quite specific about a modern-day cell. Such a cell could be( v, g) h y/ W$ Q% V
described as “a volume of cytoplasmic solvent capable of DNA-cycled,
5 l3 z" n1 s8 n6 IATP-driven and enzyme-mediated metabolism enclosed within a
8 c+ r. K5 M9 W: h0 g8 _5 n( o Aphosphor-lipoprotein membrane capable of energy transduction”, This& ~( u* z, \: B" [. {8 i; ~% b4 p
generalized specification can cover both prokaryotes (bacterial) and* f5 L9 J' T# G
eukaryotes (algal, fungal, animal, and plant cells) even though there. F: [( ]- A8 Q7 J- x
are important differences in their operation.<br/>. z0 f( \' n% q5 ?) P; }3 P
The most interesting minimal cell scenario concerns the origin of life.
" y7 w& }/ a/ R3 C- \5 h# yThe first cell need be only a very basic cell without the later& x# L7 F: a7 E
elaborations such as enzymes. Fleischaker suggests that such a cell
* T7 B2 H6 Z( C0 gmust exhibit a number of operations (Fig.2.4):<br/>5 [0 ~/ t- S) v1 X* ^( ]: _$ Z! d+ _
1、The cell must demonstrate the formation and maintenance of a boundary2 D. M5 L; Z, i, Z' _6 g1 S$ l
structure that creates a hospitable inner environment and allows
3 T& Z8 R1 J. F! |selective permeability for incoming and outgoing molecules and ions.
1 g3 f8 u) U$ N! yThe lipid bilayer found in contemporary cells is a good possibility* g1 Y" ^$ D! H+ b8 u+ Z
since the hydropholic nature of lipid molecules leads them to form
" i& p3 ^' e0 ]6 k5 a% i3 f* {, b9 C) xclosed spheres in order to avoid contact with water. Lipid bilayers are0 d& m' |, o3 { [1 b6 |0 Q: D e
also permeable in certain ways – for example, to flows of protons or* P$ L1 z- U3 K) g+ A2 |! \
sodium atoms – without the need for the complex enzymes prevalent in3 o' V4 f$ T3 X' \- m
contemporary cells.<br/>
, k# W) O6 N* ^) O' c) c2. The cell must also demonstrate some form of active energy
$ [) p, V) i, o: k& ytransduction to maintain it away from entropic chemical equilibrium.
1 @+ g6 r( b5 r' KOne possibility is an early form of photopigment system driven by
. l* [# V+ g0 klight. Pigment molecules would become embedded in the membrane and act
, z! s9 ?( M7 pas proton pumps, leading to the concentration of variety of raw
) I8 J3 }/ g/ d0 ?" W$ Nmaterial in the cell.<br/>
' U! X- f, r. F* ?/ L' i3. The cell would also need to transport and transform material, M7 d8 ]6 b3 X8 C
elements and use these in the production of the cell’s components and
& s4 t# K3 o" T* |6 Sits boundary. A possible start in this direction would be the import of
' B; X6 Z1 y% [( j/ a- qcarbon dioxide and the physio-chemical transformation of its carbon and
2 V+ g9 z. g/ y, V2 ~oxygen through light-driven carbon fixation.<br/>
! K! p9 L8 W. c: ^& A9 GWhat is important is not the particular mechanisms for any of these
% u. i6 N: _! Mgeneral operations but that whichever mechanisms are postulated, all, Y, V( {8 G2 [7 c" K
operations need to be part of a continuous network to form a dynamic,% m9 L1 f- n% Y3 T* t
self-producing whole.<br/>
' E# d$ W: ?5 I2.4.2 Chemical Autopoiesis<br/>! y8 }4 }, D- y# Y% |/ M9 e
Beyond theoretical constructs of minimal cells, it is also interesting
, q" H8 I$ g+ Bto look at attempts to identify or create chemical systems based on+ q* O$ b r& _2 f) F, m9 B5 u4 g
autopoietic criteria, and to consider whether or not these are living.4 ]( U; W/ [2 `. m6 D4 _7 V( d
We shall look at three examples: autocatalytic processes, osmotic
# [& ~* ~6 E) C. Egrowth, and self-replicating micelles.<br/>
a/ _4 ~" t/ h2 ?2.4.2.1. Autocatalytic Reactions<br/>
% y3 I4 N8 d1 J8 B4 PA catalyst is a molecular substance whose presence is necessary for the
; M6 z1 o1 `5 d, O/ ?occurrence of a particular chemical reaction, or which speeds the
4 C( ?4 V, w3 C: ?* I: K4 Oreaction up, but which is not changed by the reaction. The complex0 S( W- Y* i1 H6 u0 o& i G
productions of contemporary cells (as opposed to cells that may have
& H) r1 u* L. n* F" h# J1 a- Aexisted at the origin of life) require many catalysts, and this is one2 _6 H8 _1 m$ e4 k6 O# k
of the main functions of the enzymes. An autocatalytic process is one
9 B6 \. ]3 W; R6 ~in which the specific catalysts required are themselves produced as
# z( F" @3 L8 c7 V& X' X- l3 {by-products of the reactions. The process thus self-catalyzes. An
1 H- s" O- b. t$ d/ o/ Dexample is RNA itself which, in certain circumstances, can form a1 T( t8 I* c5 [- x* I
complex surface that acts like an enzyme in reaction with other RNA( a0 H) t7 t) G. P9 A- w# o1 h
molecules (Alberts et al.) Kauffman has a detailed discussion within
( p c8 ]% e6 P+ G* m5 D& pthe context of complexity theory.<br/>
8 u: O+ T( O8 i2 ~/ J* pAlthough this process can be described as a self-referring interaction,
. G" [6 A. t, ~- l* |0 Kthe system does not qualify as autopoietic because it does not produce0 E7 P8 n1 R: v- k; [3 x( y
its own boundary components and thus cannot establish itself as an
# A, ]) `4 Y# V( c# vautonomous operational entity (Maturana and Varela). Complex,
3 ~8 @/ w r- I) minterdependent chemical processes abound in nature, but they are not
9 f1 b( k, P0 r( W( ~0 ?6 U vautopoietic unless they form self-bounded unities that embody the4 w o! Z# ^( o; H. O" Y* p G
autopoietic organization.<br/>4 ` X; S e& C
2.4.2.2 Osmotic Growth<br/>0 w1 Q& B# j* F. q' d
Zeleny and Hufford have suggested that a particular form of osmotic
% [. k9 K& s( w: \- I, Ygrowth, studied by Leduc, can be seen as autopoietic. The growth is
7 }2 j" O [" k j! [precipitation of inorganic salt that expands and forms a permeable
/ b) x1 {' F0 Posmotic boundary. This can be demonstrated by putting calcium chloride
* G G* z3 y6 Y- v* Zinto a saturated solution of sodium phosphate. Interaction of the
) h' v0 {0 x/ }5 J7 ecalcium and phosphate ions leads to the precipitation of calcium
% c/ g: U/ p% O" G7 [phosphate in a thin boundary layer. This layer then separates the
/ e1 b! `3 `1 c% P5 i/ \/ Qphosphate from the calcium, water enters through the boundary by$ m- V& L+ P `2 o3 l
osmosis, and the increased internal pressure breaks the precipitated6 ~- I6 Q( J! |7 H- X1 Q; b
calcium phosphate. This break allows further contact between the9 s; K F4 b& q) U) Q9 M
internal calcium and the external phosphate, leading to further/ W8 J9 M! @8 C! S
precipitation. Thus the precipitated layer grows.<br/>
3 C$ O, X& \6 n3 NZeleny and Hufford argue that this system fulfills the six autopoietic criteria:<br/>( R" x4 x* L5 ?- _ I
1. It is distinguishable entity because of its precipitate boundary.<br/>
1 ^- r- J: X( v1 H8 o1 w2. It is analyzable into components such as the calcium phosphate boundary and the calcium chloride.<br/>
( F$ @3 U$ b0 A3. It follows mechanistic laws.<br/>
$ V% V6 b q2 L( ~* o8 Z4. The boundary components (calcium phosphate) aggregate because of their preferred neighborhood relations.<br/>+ T0 j& Y" F, t3 B A7 t* U, T
5. The boundary components are formed by the interaction of internal4 T. v% I. j' w7 N) @: o" I
and external components following osmosis through the membrane.<br/>
p: C, {& f: F; J7 O6. The components (calcium chloride) are not produced by the cell but! p. w# L) p4 ~0 M a2 ~
are permanent constituent components in the production of other6 ?! M! k* T; d y3 W0 I
components (the precipitate)<br/>
3 Q! n# \" p2 RThis hypothesis does cause problems, as Leduc’s system is clearly# {9 k! t; C; O ]5 U: n
inorganic and not what would be called living. If it is accepted that+ e9 u+ G7 W9 @1 S
the system does properly fulfill the criteria of autopoiesis, i.e.,5 m* G, W( t* p( H
that it is an autopoietic system as currently defined, then either we$ ^( w! R2 m- O) a( G
must expand our concept of living or accept that autopoiesis is in need) q6 S9 \# }7 I
of redefinition to exclude such examples. In fact, it is debatable
# Y- B2 m1 o, c- ~/ ?$ Awhether or not this osmotic growth does correctly fulfill the six( s. g3 U# l+ Z+ M0 R
criteria. It certainly meets the first three, but it is not clear that, e7 C$ d- D, G) Q7 w
it is a dynamic network of processes of production.<br/>
0 x6 q3 Q$ n- j5 o) cAs for the fourth criterion, the precipitate that forms the boundary is
. e5 s1 X, B1 b( J* junlike a cell membrane. It is static and inactive, more like a stone
: E2 B& X9 z% p: W" h Jwall than an active membrane. It is not formed through “preferential0 r( Q' o! F7 x2 U
neighborhood interactions”; in fact, once formed, it does not interact
$ n" m9 Y" o; \" S" [( cat all. Considering the fifth criterion, the boundary components are
5 i4 @: e5 _3 e( J2 P( ~/ N: Rnot continuously produced by the internal processes of production.' x! @5 c" }! h
Rather, a split or rupture occurs and more boundary is precipitated at
7 J7 ~) a, r5 \, D( |the split through the interaction of internal and external chemicals.- }+ m0 P! \2 v1 E
It is only because of, and at, the rupture that new boundary is
. z8 @# a) `* }: l/ k( W" } \* mproduced. Finally, chloride, which is introduced artificially at the
! F) r3 E+ |/ h' R. Ybeginning, is not produced by the system, and eventually runs out.<br/>
# h0 A* ]: j( I) h% p/ v2.4.2.3 Self-replicating Micelles<br/>
& n0 i. J3 P$ M9 E6 j7 v/ e, N4 VAn approach with more potential, currently being researched by Bachmann; i- d* u* S7 B; E0 N# g; X
and colleagues, was first proposed by Luisi. It has been discussed by# O. Z2 _% x0 w- j9 h9 `
Maddox and Hadlington. A micelle is a small droplet of an organic
# j5 H8 X1 J7 E1 i1 k; echemical such as alcohol stabilized in an aqueous solution by a
0 J% U G9 b8 _/ R2 S$ iboundary or “surfactant” A reverse micelle is a droplet of water0 ~+ S+ t# o, y! O" v
similarly stabilized in an organic solvent. Chemical reactions occur
' a1 i" _5 ^) P) M' s" h4 Y) m9 {within the micelle, producing more of the boundary surfactant., I. a+ n9 G# C0 Y( ^( r
Eventually, this leads to the splitting of the micelle and the
% U/ e5 Z) X( w: I5 vgeneration of a new one, a process of self-replication. Experiments
; O& S' ^) b* {7 V: ?have been carried out with both ordinary and reverse micelles and with
+ B1 z0 e- I; E" I; ran enzymatically driven system.<br/>( @7 J. G0 M8 v
In the reverse micelle experiments, the water droplets contain+ Y s2 ^1 y1 s$ g/ F
dissolved lithium hydroxide, one of the surfactants is sodium
6 m3 b) e, G( _2 ?2 n$ Roctanoate, and the other is 1-octanol, which is also a solvent. The
, I' u. ~+ ^9 F7 Q6 K7 R* Hother solvent is isooctane. The main reaction is one in which the( u9 ?) e% V4 _5 M/ v6 U8 r* r
components of the boundary are themselves produced at the boundary.( t7 K# X! y: `
Octyl octanoate is hydrolyzed using the lithium as a catalyst. This
6 a8 z% q. S2 x5 Uproduces both the surfactants (sodium octanoate and 1-octanol). Since& b+ j! M, U* D8 c+ _& N
the lithium hydroxide is insoluble in the organic solvent, it remains
4 v6 s6 `: O0 A) s8 Pwithin the water micelle, thus confining the reaction to the boundary
4 g" E; b: r9 I8 {; n+ ylayer. Once the system is initiated, large numbers of new micelles are& m5 R( ]8 b7 U/ r: e) t4 |
produced, although the average size of the micelles decreases.<br/>
% J( k, {2 |' a. Q% K( [ S7 }It is not clear that these systems could yet be called autopoietic.
$ }4 e; t" i' W4 FFirst, the raw materials(the water-lithium mixture or the enzyme
: ~* h; U# Q! i( V4 ~catalyst) are not produced within the system. This limits the amount of
4 }3 C% S& d+ V% Q1 Q9 Ireplication which can occur; the system eventually stops. Even if these
+ q+ Y6 z5 c" S( O) Mmaterials could be added on a regular basis, the system would still not# |* m7 N2 v; B/ J6 d
be self-producing. Second, the single-layer surfactant does not allow2 C& L, I& m, H% }& M8 P5 Y6 {3 I
transport of raw materials into the micelle. For this to happen, a4 m6 l) _% Q' @ B8 a( s# K
double-layer boundary would be necessary, as exists in actual cell- D& G, x7 g- e; u" C
membranes. Moreover, the researchers themselves, and seem most; Z6 R, {5 v! e
interested in the fact that the micelles reproduce themselves, and seem
& B5 i+ h% `) ?9 K) m5 z; oto identify this as autopoietic. However, reproduction of the whole is
( ~. F4 x' P7 H8 e* |quite secondary to the autopoietic process of self-production of
6 {! b" _& O8 E4 y3 z' _2 Ccomponents. Nevertheless, this does represent an interesting step
0 y: q g5 X9 H& i& A( h0 {toward generating real autopoietic systems. |
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