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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
群组: 数学建模 群组: 趣味数学 群组: C 语言讨论组 群组: Matlab讨论组 群组: 2011年第一期数学建模 |
英文原文:<br/>2.1 The essential idea of Autopoiesis<br/>
& q1 j: M; F* l( KThe fundamental question Maturana and Varela set out to answer is: what3 }5 _: h& D; X
distinguishes entities or systems that we would call living from other
3 v- Z) p3 o( l1 |* hsystems, apparently equally complex, which we would not? How, for2 O" A6 f0 O5 j. F% K- S h
example, should a Martian distinguish between a horse and a car? This; _( ^ `" s) c- H# F; W
is an example that Monod (1974, p. 19) uses in addressing the similar- x4 ?' B1 K: I, h- d
but not identical question of distinguishing between natural and5 c7 H! Y7 Y) v/ ]9 W! {9 K2 ^
artificial systems.<br/>
+ c- x. {3 k, `+ D/ t( h$ a" v% ?This has always been a problem for biologists, who have developed a
% d6 x1 F% ]4 k& y; _9 ^; s9 w; Jvariety of answers. First came vitalism (Bergson, 1911; Driesch, 1908),
1 G r' I5 I+ i: m7 T! fwhich held that there is some substance or force or principle, as yet
: O. X( g% t/ V! Runobserved, which must account for the peculiar characteristics of
4 h" _8 U4 u* K1 ]3 t1 s! M; plife. Then system theory, with the development of concepts such as; J/ k- I- G5 L+ H# U/ k+ ?9 B
feedback, homeostasis, and open systems, paved the way for explanations
( @- `5 h, ~8 U7 V0 oof the complex, goal-seeking behavior of organisms in purely: F% x5 J. B7 b3 I4 _
mechanistic term ( for example, Cannon, 1939; Priban, 1968). While this
. T- ~7 O/ U" u5 a" V8 S0 X5 uwas a significant advance, such mechanisms could equally well be built0 D& V2 }) T+ D9 W
into simple machines that would never qualify as living organisms.<br/>
\. f( v* S2 ` {* ?6 l( ]A third approach, the most common recently, is to specify a list of1 X" e/ K! `0 X0 i6 U# d8 V
necessary characteristics that any living organism must have – such as& e3 K' o% x/ l7 H( _+ g
reproductive ability, information-processing capabilities, carbon-based
9 F1 E4 Q2 ]& k0 r# lchemistry, and nucleic acids (see, for example, Miller, 1978; Bunge,6 h* v) h, o0 w ?
1979). The first difficulty with this approach is that it is entirely
z/ ~9 g1 F, D: Wdescriptive and not in any real sense explanatory. It works by& ]8 o8 A- z. o6 S- ~% d
observing systems that are accepted as living and noting some of their
3 w; h0 ^% ?/ s" Q& L) Lcommon characteristics. However, this tactic assumes precisely that
8 i& A1 N6 c( rwhich is in need of explanation – the distinction between the living
6 [' H3 @) d; b4 Tand the nonliving. The approach fails to define the characteristics
3 u; B. C" R* ?& K' N9 n& F( @particular to living systems alone or to give any explanation as to how m6 X( |( j" r/ X& Q$ Y
such characteristics might generate the observed phenomena. Second,& T: t: A) j% t4 U, n" j- M$ j
there is, inevitably, always a lack of agreement about the contents of* E+ Z; V/ d/ Z0 D; x
such lists. Any two lists will contain different characteristics, and2 z) l1 m q i% W
it is difficult to prove that every feature in a list is really+ `7 ^4 B# Z7 t
necessary or that the list is actually complete.<br/>7 F. }( q2 L& B' l [/ Y8 w* s( u
Maturana’s and Varela’s work is based on a number of fundamental4 }9 x, z0 k3 D) f6 n. \9 H! Y
observations about the nature of living systems. They will be/ F+ J5 S/ K/ P$ d9 }
introduced briefly here but discussed in more detail in later chapters.<br/>
" _+ i& p/ y. s1 M$ Q1. Somewhat in opposition to current trends that focus on the species; f- G c# p- Z& c
or the genes (Dawkins,1978), Maturana and Varela pick out the single,8 z: X9 d$ F- u! t, T8 }% L, f
biological individual (for instance, a single celled creature such as, M+ e" l$ t! J, z, ?1 x
an amoeba) as the central example of a living system. One essential% i' Q( ]; B- w+ f
feature of such living entities is their individual autonomy. Although& q1 } W7 b. @, I
they are part of organisms, populations, and species and are affected
0 P$ L/ T3 P( D6 p4 }* tby their environment, individuals are bounded, self-defined entities.<br/>0 c) W, N/ y5 ?+ n
2. Living systems operate in an essentially mechanistic way. They, O9 ^3 T% \. H, g B+ J: a0 n
consist of particular components that have various properties and5 U* n, [/ m& q( P2 k* _8 c, `# }
interactions. The overall behavior of the whole is generated purely by
( Z2 p6 N# d+ u3 Sthese components and their properties through the interactions of9 b% d8 z5 }; c9 g: G7 P) o
neighboring elements. Thus any explanation of living systems must be a6 q# j- G$ ]& I }# W0 p. q( D% r+ b
purely mechanistic one.<br/> u! y$ b" m) L( n/ N V2 F' ]- i( S
3. All explanations or descriptions are made by observers (i.e.,
. f% n* a/ ]9 Q) H4 Q/ gpeople) who are external to the system. One must not confuse that which& u F" c0 F- Y, e! r. f
pertains to the observer with that which pertains to the observed.5 M# l& X9 K9 e
Observers can perceive both an entity and its environment and see how5 m- N% K+ [7 N& Z. q- b8 G8 m
the two relate to each other. Components within an entity, however,
; _9 s; m% Z: P' {: P& p! S8 Vcannot do this, but act purely in response to other components.<br/>/ R9 Q4 k, |. W0 g
4. The last two lead to the idea that any explanation of living systems
- n- Y5 x$ C2 k8 ?; l* y/ z# eshould be nonteleological, i.e., it should not have recourse to ideas. r# d, W7 a+ b v
of function and purpose. The observable phenomena of living systems
7 a4 f% x+ ^$ ?7 Iresult purely from the interactions of neighboring internal components.& T# J7 ~9 f! ^$ V L* |- a
The observation that certain parts appear to have a function with
% } D, P5 u$ G" S5 e% J; m0 y6 b) jregard to the whole can be made only by an observer who can interact' n( ^7 U4 B, @7 Q3 ]
with both the component and with the whole and describe the relation of
! h8 i6 R% H, c5 ]- Ythe two.<br/>$ R% d# U# [. ]- H
<br/>
/ o& o5 e7 H, P, W, R7 KTo explain the nature of living systems, Maturana and Varela focus on a5 O0 f; y* W' N( C) V, M5 P# ^
single basic example – the individual, living cell. Briefly, a cell# |' R( m: I" {" Z. A- M
consists of cell membrane or boundary enclosing various structures such
4 D. t: |# G" @' f8 |% Q; Bas nucleus, mitochondria, and lysosomes as well as many (and often
2 z$ i6 z$ f5 y! U* l* I6 c6 Ncomplex) molecules produced from within. These structures are in4 Q) P! t( N$ W$ w
constant chemical interplay both with each other and, in the case of
- l) p% d. N3 l1 V% H" f7 `the membrane, with their external medium. It is a dynamic, integrated
: l- |' a: t0 E6 nchemical network of incredible sophistication (see for example Alberts+ a3 @% U M; I
et al.,1989; Raven and Johnson,1991).<br/>
+ y; G( ?; B& a" kWhat is it that characterizes this as an autonomous, dynamic, living( T: h# O3 a' L8 U6 @% F Q$ h
whole? What distinguishes it from machine such as a chemical factory5 y2 H3 X$ R9 u5 r" C
which also consists of complex components and interacting processes of
: R# u: e' ^5 X: k! _4 Xproduction forming an organized whole? It can not be to do with any W6 v$ J0 |: W; H+ Z- {' t
functions or purposes that any single cell might fulfill in a larger
3 T$ D0 w" j8 J ]# H: vmulti-cellular organism since there are single-cellular organisms that4 ^( n/ G5 {0 f; S
survive by themselves. Nor can it explained in a reductionist way8 u, I2 [* q: Z3 ?6 C- u
through particular structures or components of the cell such as the; ^# a/ Z2 `4 _( ^" K
nucleus or DNA/RNA. The difference must stem from the way of the parts* y2 Y- I& r3 B% o
are organized as a whole. To understand Maturana and Varela’s answer,2 P. y" r/ @) u5 P: A
we need to look at two related questions – what is it that the cell
! P/ y' f. H K1 j8 V- ]does, that is what is it the cell produces? And what is it that
, }; T: ]! l: |- Q6 l3 _ uproduces the cell? By this I mean the cell itself rather than the
3 t# W: K9 X3 D. Yresults of their reproduction.<br/>
/ Z1 y& z. K/ W$ bWhat does a cell do? This will be looked at in detail in Section 2.3% q- H# M' G; F
but, in essence, it produces many complex and simple substances which
- a9 X. v1 c0 I3 cremain in the cell (become of the cell membrane) and participate in
) D1 t4 `5 W" T9 \5 fthose very same production processes. Some molecules are excreted from, A$ f# w# ^! ^; k# {5 m$ ]
the cell, through the membrane, as waste. What is it that produces the
! x: j& y; E3 i% [& dcomponents of the cell? With the help of some basic chemicals imported
2 w* P! t8 c( K3 q/ t( I4 Lfrom its medium, the cell produces its own constituents. So a cell3 Q; t1 a/ B$ S3 M
produces its own components, which are therefore what produces it in a& Y( t1 q; T' u
circular, ongoing process (Fig. 2.1)<br/>
. x" A" `/ C% `' i6 ?7 o' x BIt produces, and is produced by, nothing other than itself. This simple* R' E. M2 {+ `
idea is all that is meant by autopoiesis. The word means
: c) x Z0 z9 `5 k: D5 q: p$ d“self-producing” and that is what the cell does: it continually
% z# `( \: X$ N1 Aproduces itself. Living systems are autopoietic – they are organized in- M" @. Q& e/ n# u" i, _
such a way that their processes produce the very components necessary
4 B" u6 X8 X. j: [for the continuance of these processes. Systems which do not produce
" i' ]: S7 F6 v4 L7 N( y0 T4 Ythemselves are called allopoietic, meaning “other-producing” – for9 d ^) @& q* Z! q7 R9 A' X* x
example, a river or a crystal. Maturana and Varela also refer to
7 f4 k" R6 V0 D* h# chuman-created systems as heteropoietic. An exemple is a chemical
5 h- Z$ t7 ^ K( q# n: l: Jfactory. Superficially, this is similar to cell, but it produces* V1 d4 c% B# z' d+ ~5 w y
chemicals that are used elsewhere, and is itself produced or maintained
/ _* g+ R. z9 e2 v0 j1 J6 gby other systems. It is not self-producing.<br/>- `0 R2 q4 C9 c" M' o2 Z
At first sight this may seem an almost trivial idea, yet further contemplation reviews how significance it is. For example:<br/>
4 |' Y+ `4 G4 o6 h1 X. K1. Imagine try to build autopoietic machine. Save for energy and some0 ^$ n' U/ o. `
basic chemicals, everything within it would itself have to be produced# f" u& {6 b/ q8 R4 t; V
by the machine itself. So, there would have to be machines to produce4 t4 B" V' C8 U6 G! Q
the various components. Of course, these machines themselves would have
3 _( P* N5 {- F3 P9 g% pto be produced, maintained, and repaired by yet more machines, and so
. s, f& D2 k) _on, all within the same single entity. The machine would soon encompass
8 X; w; C- N( {2 h4 K1 uthe whole economy.<br/>1 t1 S. s, A$ d/ w( ]* @6 Q8 j
2. Suppose that you succeed. Then surely what you have created would be, U7 N) a% F7 w) p0 W5 N0 a2 g
autonomous and independent. It would have the ability to construct and
* Y' k% j; G' D) P* T& `& [5 P \reconstruct itself, and would, in a very real sense, be no longer; r9 y3 N4 A# c" P6 a) D
controlled by us, its creators. Would it not seem appropriate to call) P4 O% \( R" v$ N2 L% G5 }
it living?<br/>
5 S0 ^* P; v' R; C2 K+ G3. As life on earth originated from a sea of chemicals, a cell in which
6 P! l u6 W9 {# u# \a set of chemicals interacted such that the cell created and re-created
& }6 w. d2 X% `* S8 }its own constituents would generate a stable, self-defined entity with& X1 i7 r4 I. R* p& @1 z
a vastly enhanced chance of future development. This indeed is the
% Q/ i/ [3 w" N `8 @( x3 _& |basis for current research, to be described in section 2.4.1<br/>
% g. c, Y, A5 ]' ^" @8 a4. What of death? If, for some reason, either internal or external, any. J/ _6 v7 W- e
part of the self-production process breaks down, then there is nothing% c3 e4 U. Z" A4 f
else to produce the necessary components and the whole process falls
7 Y! S4 }' k, q! C J% ]apart. Autopoiesis is all or nothing – all the processes must be2 s$ j: n9 p5 j y8 j
working, or the systems disintegrates.<br/>
; |" J: O6 r5 B( JThis, then, is the central idea of autopoiesis: a living system is one
7 ?1 O- G6 j, v | qorganized in such a way that all its components and processes jointly
3 ?2 L% D2 l* e$ g7 p, j8 Nproduce those self-producing entity. This concept has nearly been/ ^5 q9 G2 [* k; C3 T
grasped by other biologists, as the quotation from Rose at the start of
. ^. S- r. s( C, a8 a K, J4 athis chapter shows. But Maturana and Varela were the first to coin a
, @; V3 d: B3 ^" ]% O+ kword for this life-generating mechanism, to set out criteria for it4 F/ V! |( H# R: n9 v$ V
(Varela et al., 1974), and to explore its consequences in a rigorous. f" `4 R6 ~( v; Y; E
way.<br/>
, B% u" @% v7 F$ i- y$ q! iConsidering the derivation of the word itself, Maturana explains that
9 }7 f8 B, X$ ihe had the main idea of a circular, self-referring organization without
, X. g# r1 U7 j8 N8 v) o, |the term autopoiesis. In fact, biology of cognition, the first major h! H& E' X5 t! i# W* F
exposition of the idea, does not use it. Maturana coined the term in
6 o, k& X. J$ q" w! [- vrelation to the distinction between praxis (the path of arms, or
0 {. \ C. F% @ {. jaction) and poiesis (the path of letters, or creation). However, it is G) Z; [4 T7 Z6 M) N% T
interesting to see how closely Maturana’s usage of auto- and
, b3 Q; |4 E3 b, w& v6 V; X8 h4 rallopoiesis is actually foreshadowed by the German phenomenological
4 I% z8 K& g. d9 |+ D( E" g$ fphilosopher Martin Heidegger. In the quotation at the start of Chapter
# Q* K& i( ^) ~1, Heidegger uses the term poiesis as a bringing-forth and draws the
" M* T: a) W4 r% h h* d4 v" L( mcontrast between the self-production (heautoi) of nature and the i* m8 \' G: [8 i3 y. V$ i
other-production (alloi) that humans do. Heidegger’s relevance to, P6 ~, O) u. i) A A" h
Maturana’s work will be considered further in Section 7.5.2<br/>
, x* A4 _/ R8 h \8 d; A \! U u2.2 Formal Specification of Autopoiesis<br/>
9 M+ i7 b w0 S7 ^" ] L) ENow that I have sketched the idea in general terms, this section will% r7 W6 G; E' D' X; m. m
describe in more detail Maturana’s and Varela’s specification and
( [5 c6 _- g& Q$ Q4 |vocabulary.<br/>& H1 m5 P2 U# W0 d
We begin from the observation that all descriptions and explanations/ ]" `: v( o4 `# h) A4 A1 C/ e
are made by observers who distinguish an entity or phenomenon from the" k2 A0 p! D/ E+ E
general background. Such descriptions always depend in part on the) D$ U" M' B: X8 B5 |0 a
choices and processes of the observer and may or may not correspond to( S* C7 u! _% s) L5 a. \* K5 s
the actual domain of the observed entity. That which is distinguished q+ Y- g F2 S8 @4 Q3 _) Y
by an observer, Maturana calls a unity, that is, a whole distinguished
* l) E0 E* j( O. Y: Mfrom a background. In making the distinction, the properties which
4 n$ N0 k" d, ?, Kspecify the unity as a whole are established by the observer. For
2 g6 m3 g# ~5 A8 Sexample, in calling something “a car,” certain basic attributes or
6 o; T0 k+ y7 edefining features (it is mobile, carries people, is steerable) are
) N2 W2 a5 j$ H8 V) U$ Aspecified. An observer may go further and analyze a unity into0 i0 p. B# w- u# W( i
components and their relations. There are different, equally valid,
2 x$ c' m8 h: B5 Y8 vways in which this can be done. The result will be a description of a2 K$ m" n% }0 ^3 q+ H
composite unity of components and the organization which combines its
# X9 w3 y' Z2 Ocomponents together into a whole.<br/>
9 d \* v/ F, IMaturana and Varela draw an important distinction between the organization of a unity and its structure:<br/>: ` b/ N- T: N6 y* X1 h
[Organization]refers to the relations between components that define
* }0 q3 q( s+ h& m1 n$ X7 tand specify a system as a composite unity of a particular class, and
8 R W j1 L4 Q% w! Pdetermine its properties as such a unity … by specifying a domain in
8 [' g |: [# h8 _which it can interact as an unanalyzable whole endowed with: `, {* }0 G/ ]1 S% T: b: U
constitutive properties.<br/>6 h, v8 f- d/ R- r4 A' A
[Structure] refers to the actual components and the actual relations
* c9 s% L x/ f# A1 ^. v/ S; zthat these must satisfy in their participation in the constitution of a9 G. o3 r L$ |
given composite unity [and] determines the space in which it exists as
( F c$ w; w0 {a composite unity that can be perturbed through the interactions of its- {" Y, A$ f: n
components, but the structure does not determine its properties as a3 e: N) G9 u# Y3 `
unity.<br/>
% ^0 ?9 Y5 _% H0 `0 hMaturana (1978, p. 32)<br/>
9 W9 Y3 T, Q" {; p mThe organization consists of the relations among components and the
+ \3 ^$ O; h" m$ R0 t" lnecessary properties of the components that characterize or define the+ m% j5 u S+ g* u7 d
unity in general as belonging to a particular type or class. This, P. P7 l/ p/ `' q
determines its properties as a whole. At its most simple, we can
- G0 u) r" ~2 D2 M' s0 L+ p* uillustrate this distinction with the concept of a square. A square is
8 Y9 J6 A- U. }defined in terms of the (spatial) relations between components – a
6 y0 r" T$ w( d! t7 S3 o+ gfigure with four equal sides, connected together at right angles. This* x' C1 d- D1 n8 }3 S
is its organization. Any particular physically existing square is a" y: o# X) Z! z2 a; [
particular structure that embodies these relations. Another example is3 N5 z0 x4 D. B9 A. K: z6 @1 l2 ]
a an airplane, which may be defined by describing necessary components3 J* Z3 x6 D: `- m& c" p
such as wings, engines, controls, brakes, seating, and the relations
7 D# K- p& g2 L+ [4 Ibetween them allowing it to fly. If a unity has such an organization,
a2 }/ ]; i/ wthen it may be identified as a plane since this particular organizatio
- [: B7 H) Q" Uwould produce the properties we expect in a plane as a whole." H @+ l/ S0 a( ^& H
Structure, on the other hand, describes the actual components and& X% _$ k: j) H% ~) D
actual relations of a particular real example of any such entity, such' n. F4 U5 K8 Q3 n+ V' T
as the Boeing 757 I board at the airport.<br/>
' E: m& f0 H1 L4 i. J8 oThis is a rather unusual use of the term structure (Andrew, 1979).
& D9 b: K+ e. vGenerally, in the description of a system, structure is contrasted with
* f& p* T& t4 ^5 ^- vprocess to refer to those parts of the system which change only slowly;. l& ^: x3 u1 D; }5 J; y9 B9 J
structure and organization would be almost interchangeable. Here,1 Q) b+ t+ w; A. F3 I( V
however, structure refers to both the static and dynamic elements. The( J2 E5 d4 ~1 `; S$ H$ g7 \# b7 j7 n
distinction between structure and organization is between the reality
+ c- ~% ?9 ~' _" Rof an actual example and the abstract generality lying behind all such& H5 I/ ~8 u0 f* ]$ X
examples. This is strongly reminiscent of the philosophy of classic( [- W! [3 |8 Y Q4 y
structuralism in which an empirical surface “structure” of events is4 S( K+ s: x& `# I# ]6 m
related to an unobservable deep structure (“organization”) of basic
5 O( S7 e0 m/ u6 A8 z+ P# F. krelationships which generate the surface.<br/>
7 U8 @; ]+ p, X) m3 BAn existing, composite unity, therefore, has both a structure and an. m" B" Y Y# x$ K Z. y I# K1 W
organization. There are many different structures that can realize the
5 T( a6 F' }8 K/ p- l& j5 X( Dsame organization, and the structure will have many properties and$ a* x2 q: p1 z7 }$ @5 t! T7 w5 J
relations not specified by the organization and essentially irrelevant
4 q$ ?& A- \) J, g, E" C' mto it – for example, the shape, color, size, and material of a
, T3 C5 K6 }( f0 U$ k3 U4 O# Vparticular airplane. Moreover, the structure can change or be changed
8 {2 h* R$ d; d1 g! ?9 N4 @1 mwithout necessarily altering the organization. For example, as the
3 m' e' J" [% qplane ages, has new parts installed, and gets repainted it still
9 e4 O B5 u3 D j" H0 Fmaintains its identity as a plane because its underlying organization8 f- `1 d8 u5 ^6 V* T
has not changed. Some changes, however, will not be compatible with the
: L9 O! v) B9 O' `+ U' k, Tmaintenance of the organization – for example, a crash which converts, R/ `, s- n" C$ [* c$ [9 J
the plane into a wreck.<br/>
) q8 a" p6 f; L( m9 J3 ^! r- U9 KThe essential distinction between organization and structure is between2 Z# S/ H# a2 _: s t( B* a2 S
a whole and its parts. Only the plane as a whole can fly – this is its. r/ ~# H5 v$ H" s- N
constitutive property as a unity, its organization. Its parts, however,% R. B' c0 L; ?+ h+ b* T7 J
can interact in their own domains depending on all their properties,
' o& ?$ l. \7 I4 D1 }# g" xbut they do so only as individual components. Sucking in a bird can
4 K. s t; v6 v: V- v- Gstop an engine; a short circuit can damage the controls. These are
9 ?4 |% k- o8 Q" xperturbations of the structure, which may affect the whole and lead to+ A1 x5 G# w( h$ X0 t
a loss of organization or which may be compensable, in which can the& n% o+ `: T$ x; s1 W/ _8 F
plane is still able to fly.<br/>
6 p' V: y, Z. A% YWith this background, we can consider Maturana’s and Varela’s
$ w$ Y R: ?" Zdefinition of autopoiesis. A unity is characterized by describing the
' \1 U2 U _) J3 U: [organization that defines the unity as a member of a particular class8 e+ Q. K" Q# A2 F6 h
that is, which can be seen to generate the observed behavior of unities
& J$ f8 i6 U2 p5 }1 m0 k$ w$ Vof that type. Maturana and Varela see living systems as being
6 d6 G, C! ^, Z! Y6 Q( oessentially characterized as dynamic and autonomous and hold that it is
2 J4 ]) D8 N1 C8 O! Jtheir self-production which leads to these qualities. Thus the9 U4 o7 |; u4 @9 t/ c' F/ I# V* `" M
organization of living systems is one of self-production – autopoiesis.
$ K0 v# E, x6 g- Z2 WSuch an organization can, of course, be realized in infinitely many; V" M& y/ S' ~
structures.<br/>
% E: C! d3 {' z8 h! e- J5 ]' nA more explicit definition of an autopoietic system is<br/>+ [" U4 A, m, ]" g
A dynamic system that is defined as a composite unity as a network of productions of components that,<br/>' S G( _9 W3 F: x* \' i
a) through their interactions recursively regenerate the network of productions that produced them, and <br/>. l/ Q7 U/ N" J& P
b) realize this network as a unity in the space in which they exist by9 S. G' e5 ~: `! k9 C) H4 q) B
constituting and specifying its boundaries as surfaces of cleavage from
5 C) P: \1 h6 x4 f( ~the background through their preferential interactions within the
; O) [5 H; d+ K7 h1 n4 e$ Enetwork, is an autopoietic system. Maturana (1980b, p. 29)<br/>
& {- f5 S7 ~( t' W+ {8 ?The first part of this quotation details the general idea of a system1 M# r0 m* j. k# J2 M. t
of self-production, while the second specifies that the system must be4 I1 M2 E4 O( M9 ~4 O& K, L
actually realized in an entity that produces its own boundaries. This
1 ~. w$ v& T/ I7 i4 }6 Z4 O; xlatter point, about producing boundaries, is particularly important
+ N0 V' Z9 O, Q$ |) I# d2 s4 awhen one attempts to apply autopoiesis to other domains, such as the
, E! C; Z/ x4 \- x8 ksocial world, and is a recurring point of debate. Notice also that the
. N2 W1 R' U( L4 Vdefinition does not specify that the realization must be a physical, _: z6 W9 n$ f$ e7 k9 z( N( k
one, although in the case of a cell it clearly is. This leaves open the
/ E- a9 v9 V2 q. r! M( q7 gidea of some abstract autopoietic systems such as a set of concepts, a
* O0 I4 R0 z7 y7 ]; K5 kcellular automaton, or a process of communication. What might the J9 f4 c/ Q- d% C
boundaries of such a system be? And would we really want to call such a
- j2 A8 x8 |2 H/ i8 J4 asystem “living”? Again, this is the subject of much debate – See* k9 w2 Q$ z' R, G9 o- K7 K
section 3.3.2<br/>
& c) b# t/ y v0 e3 T9 @. ?: |4 pThis somewhat bare concept is further developed by considering the
& @( {: |( ?. Q+ Z) }nature of such an organization. In particular, as an organization it' t J# r& `5 N0 q9 t! E/ Y0 o8 d
will involve particular relations among components. These relations, in
; o1 \' N4 [0 _6 E/ J" ithe case of a physical system, must be of three types according to
8 B6 o4 X* C9 ~( L) jMaturana and Varela (1973): constitution, specification, and order.4 X# }0 ~8 m% P
Relations of constitution concern the physical topology of the system
; N3 J9 Y/ v- e(say, a cell) – its three-dimensional geometry. For example, that it
# T% e8 f8 O8 xhas a cell membrane, that components are particular distances from each; `, C4 ~1 [/ ?0 `/ f
other, that they are the required sizes and shapes. Relations of
5 t6 U7 H) R$ o. e/ Ospecification determine that the components produced by the various
4 j4 O% h% `* C6 vproduction processes are in fact the specific ones necessary for the, Y6 y1 E3 [ v8 {3 ^; c8 g. q; h" F
continuation of autopoiesis. Finally, relations of order concern the
0 n% ]% k# d% j/ o: C- V7 edynamics of the processes – for example, that the appropriate amounts
$ ^; N* F, Q- L- n/ L" [4 ]" B1 Zof various molecules are produced at the correct rate and at the; c9 W9 b I& x
correct time. Specific examples of these relations will be given later,
9 C( W- o" q) Nbut it can be seen that these correspond roughly to specifying the, b% a! @- H; ]! [
“where”,”what”, and “when” of the complex production processes T9 @2 ~6 P2 O3 m. c
occurring in the cell.<br/>
; F y) N) B$ K; R& FIt might appear that this description of relations “necessary” for! h9 t0 e1 J& k, p" c7 x6 L
autopoiesis has a functionalist, teleological tone. This is not really ^4 [. P# Y- J
the case, as Maturana and Varela strongly object to such explanations.
) C4 t$ l. P$ C: p! n a* DIt is simply that, if such components and relationships do occur, they
% z: w: {3 `+ t" R9 D3 l6 Rgive rise to electrochemical processes that themselves produce further( F- n' n- F' O/ W
components and processes of the right types and at the right rates to2 r3 N8 M5 J" f: V( Q2 E: B
generate an autopoietic system. But there is no necessity to this; it
! j0 \ S7 Z# f& f5 j: Pis simply a combination that does, or does not, occur, just as a plant
: z N- c! f- ]! M3 K: Gmay, or may not, grow depending on the combination of water, light, and/ D! }9 Y2 Z: K' b' g5 c9 w5 c
nutrients.<br/>4 b' l# E; O7 ?
In an early attempt to make this abstract characterization more
3 E) R1 o8 u5 t$ Aoperational, a computer model of an autopoietic cellular automaton was, G/ [8 S$ [ @" i N
developed together with a six-point key for identifying an autopoitic5 m' H+ Y3 U) d/ i( S0 c
system (Varela et al., 1974). The key is specified as follows:<br/>
6 n/ k+ K) q* R S! pi) Determine, through interactions, if the unity has identifiable9 Q8 X5 u$ n9 u! ?% k# u8 I$ v
boundaries. If the boundaries can be determined, proceed to 2. If not,2 @/ P- u; U6 V+ {5 l i5 \) E
the entity is indescribable and we can say nothing.<br/>
1 o1 r6 A2 [5 {ii) Determine if ther are constitutive elements of the unity, that is,
) B+ D. }' ^9 ?components of the unity. If these components can be described, proceed- T( h& L* j% S4 O9 ]
to 3. If not, the unity is an unanalyzable whole and therefore not an" `$ V, T0 v0 N8 W+ ^( q) [8 B
autopoietic system.<br/>
% U% m5 I. A- {- }6 z) L3 hiii) Determine if the unity is a mechanistic system, that is, the* M2 Q5 G W( X9 ? ~
component properties are capable of satisfying certain relations that0 ]; z+ A( M* L1 ^% {+ {9 q
determine in the unity the interactions and transformations of these: i: S1 v9 s* K* B
components. If this is the case, proceed to 4. If not, the unity is not( b4 H" P! a+ w0 A; ]8 l6 C* r
an autopoietic system.<br/>& t# Z7 t8 R* M2 } H
iv) Determine if the components that constitute the boundaries of the0 _/ g [: u' t# q5 S: k4 [5 ]
unity constitute these boundaries through preferential neighborhood
( v# Q: v o1 Binteractions and relations between themselves, as determined by their2 d9 p$ M; _7 P0 O" L
properties in the space of their interactions. If this is not the case,
: c" R6 Z: ]' cyou do not have an autopoietic unity because you are determining its
2 d1 X# D4 G0 j) w" p! h6 f/ Qboundaries, not the unity itself. If 4 is the case, however, proceed to
$ U" L/ {( j. f& W9 g5.<br/>
+ e/ [3 `# Q7 C9 }( bv) Determine if the components of the boundaries of the unity are
( J q! s2 G+ o* U8 o, vproduced by the interactions of the components of the unity, either by
& c0 b' S+ S5 q6 e& btransformation of previously produced components, or by transformations1 p! C! c( z: Y6 h- V" t
and/or coupling of non-component elements that enter the unity trough" D- B( k: D% M& R5 x& E% _' b
its boundaries. If not, you do not have an autopoietic unity; if yes4 ?& p6 U- g; p) v% X
proceed to 6.<br/>
& }( F/ U# P9 h3 T3 f% E8 X) n4 K! `vi) If all the other components of the unity are also produced by the
e$ E$ \ D$ e/ n' \( {2 m2 ^interactions of its components as in 5, and if those which are not
: Z, E5 P+ Z7 K8 q4 U: v9 N$ sproduced by the interactions of other components participate as! I) l( K% k. V' E
necessary permanent constitutive components in the production of other
# y. [) V2 v6 gcomponents, you have an autopoietic unity in the space in which its0 U9 T- i, g) z; }8 d; I
components exist. If this is not the case, and there are components in( {! N& E* i* p8 U/ a( E+ K; d, M
the unity not produced by components of the unity as in 5, or if there5 J/ U' ]# T' S7 t G: N! P4 ]
are components of the unity which do not participate in the production* p0 d+ n# z9 c; r3 U! u3 _$ S
of other components, you do not have an autopoietic unity.<br/>$ w7 \: l; B2 V2 x
The first three criteria are general, specifying that there is an" ]- ]3 s8 u( R1 c
identifiable entity with a clear boundary, that it can be analyzed into
/ \% t+ p) C0 e1 A5 U2 e! l7 ^" Rcomponents, and that it operates mechanistically, i.e., its operation
$ F6 V8 f- N( N6 _: his determined by the properties and relations of its components. The" C7 s6 F/ z8 u# g" u8 t: b+ g
core autopoietic ideas are specified in the last three points. These
; ^7 Q. H/ z' _! Bdescribe a dynamic network of interacting processes of production (vi),( K& i1 ^( E( j3 _+ E4 N% W
contained within and producing a boundary (v) that is maintained by the' s2 L* F$ L2 n$ n4 J
preferential interactions of components. The key notions, especially
, J' C% I2 ?8 r0 g% Lwhen considering the extension of autopoiesis to nonphysical systems,
. V# E; W+ x8 @) S3 {2 nare the idea of production of components, and the necessity for a
) P# A. S; Q. S- Tboundary constituted by produced components.<br/>
" A' X2 p* U; I+ V& c, ~8 t/ EThese key criteria will be applied to the cell in the next section.
6 T6 H7 P: O s7 PThis section will describe briefly embodiments of the autopoietic
$ r. @8 x9 _, E brelations outlined above in the chemistry of the cell. Alberts et al.2 p# I6 W. E1 |9 Y" A
or Freifelder are good introductions to molecular biology, as is Raven
' Y o' v; q: i* f3 O3 f( M+ w/ M5 dand Johnson to the cell.<br/>2 h( P$ C5 Z5 E
2.3 An illustration of Autopoiesis in the Cell<br/>
7 |7 ~- Y( y. h7 K, cThis section will describe briefly embodiments of the autopoietic+ j- Q9 m8 b4 {% ?
relations outlined above in the chemistry of the cell. Alberts et al.
, }6 ]- U' V1 v$ z5 K; U& C2 aare good introductions to molecular biology, as is Raven and Johnson to
1 X {. v$ p# X5 ethe cell.<br/>
$ t5 T0 u' ]& O) M* z$ [) l2.3.1 Applying the Six Criteria<br/>7 f6 q( y2 ]: b$ [
Zeleny and Hufford analyze a typical cell with the six key points. A; R( d, k8 y% \8 a
schematic of two typical cells is shown in Fig 2. One is a eukaryotic
1 n4 J+ N2 y+ x; A2 `+ ycell, i.e., one that has a nucleus, and the other is a prokaryotic
$ Z5 g$ F h. s. _3 d$ N* c! \cell, which does not.<br/>! ^. }3 ` x; W5 x. l4 \: [2 Z. w
1. The cell has an identifiable boundary formed by the plasma membrane. Thus, the cell is identifiable.<br/>
# w! E- H! M H$ c( z2.The cell has identifiable components such as the mitochondria, the" ^3 P$ B( _( v) q; ]7 i4 B
nucleus, and the membranous network known as the endoplasmic reticulum.2 t/ k: v( o4 z
Thus, the cell is analyzable.<br/>( h$ _4 i- x+ g0 _; F4 I( X, x7 H
3. The components have electrochemical properties that follow general
# I, W& E' \: W2 `physical laws determining the transformations and interactions that
! j# J! C/ C6 v; |9 Y% Q! Y7 Zoccur within the cell. Thus, the cell is a mechanistic system.<br/>; ]8 _! v$ k4 ~
4.The boundary of the cell is formed by a plasma membrane consisting of
% w/ P6 `1 M9 zphospholipids molecules and certain proteins (fig 3). The lipid
# S+ K, q/ S1 x; k# P' gmolecules are aligned in a double layer, forming a selectively
4 @' X, U* K3 W/ G0 ^- Apermeable barrier; the proteins are wedged in this bilayer, mediating8 l, T8 V4 o! A: k& m
many of the membrane functions. A lipid molecule consists of two parts- \# g& R! n. l, [6 l; L/ y! M
– a polar head, which is attracted to water, and a hydrocarbon (fatty)5 F# f" d1 H* D, S" Z+ o9 D, k+ q
tail, which is repelled. In solution, the tails join together to form9 K6 m6 K9 ?: H% N
the two layers with the heads outside. The integral proteins also have$ r1 `1 M0 r4 [3 Q. L
areas that seek or avoid water. The boundary is therefore- h, }1 O1 x4 |2 b
self-maintained through preferential neighborhood relations.<br/>) y$ r' d8 t# f& s8 ?
5. The lipid and protein components of the boundary are themselves+ J4 h+ q8 P& @4 M D
produced by the cell. For example, most of the lipid molecules required/ w) y! V% ~) l2 Z. S. o; T. \
for new membrane formation are produced by the endoplasmic reticulum,
) \3 p/ V1 V' c K& ]$ Fwhich is itself a complex, membranous component of the cell. The
: {9 Q( Q; _$ _8 F0 Nboundary components are thus self-produced.<br/>8 V, o1 e3 K+ Q) M
6. All of the other components of the cell (e.g., the mitochondria, the
: y; o6 o! E" j6 qnucleus, the ribosomes, the endoplasimic reticulum) are also produced
4 ~( i# M. y7 @ |by and within the cell. Certain chemicals (such as metal ions) not
. h/ F8 i- y0 ]/ f& Vproduced by the cell are imported through the membrane and then become3 b' m, }% j2 k
part of the operations of the cell. Cell components are thus
' r H% Q" c* }0 W7 d7 Qself-produced.<br/>1 p# J9 }+ \5 V0 i3 {- \- Y, a
2.3.2 Autopoietic Relations of Constitution, Specification, and Order<br/>
% f" E8 d) M/ r- vApart from the six-point key, autopoiesis was also defined by three
4 l- `' d. g0 E, D b! _necessary types of relations. These can be illustrated as follows for a
" u4 u* V, l' ~6 ltypical cell.<br/>
* A" Y. o- t K! V; c! t2.3.2.1 Relations of Constitution<br/>
; r+ \& ?, G7 l! T1 r6 K+ f6 Z( XRelations of constitution determine the three-dimensional shape and
# `3 C; g5 X! K( Ystructure of the cell so as to enable the other relations of production
" z. M% `0 S- L( y. Rto be maintained. This occurs through the production of molecules
' ?. [( L9 |* @7 k+ X& E+ r! _which, through their particular stereochemical properties, enable other
) q$ H' S) a* Aprocesses to continue.<br/>
# I$ t& @+ v: w$ `) r+ _. J* Y, f% aAn obvious example is the construction of membranes or cell boundaries.
% v8 A0 n1 \9 \) L% w9 KIn animal cells, the membrane surrounding the mitochondria, like that+ z4 w( c: c0 K2 `4 x c
around the cell itself, serves to harbor cell contents and control the
$ V- G/ I7 q. v6 i. \rate of reaction through diffusion. Various reactive molecules are4 \1 _ w8 j! n+ O+ d4 x
distributed along the inner membrane in an appropriate order to allow; G8 Y i5 r u& i- Z
energy-producing sequences to proceed efficiently. In plant cells, in
5 \) h$ p" z1 d) l. x9 E2 Vaddition to the plasma membrane, there is a cell wall, which consists& K/ e4 S8 G: t' x2 [# ?
of cellulose, a material made up of long, straight chains of glucose5 j" g) C/ E3 E0 Q" d
units packed together to form strong rigid threads. These give plants
) W" z6 c. V: t0 H* z+ @their rigidity.<br/>
3 J) C* h5 u9 R9 j! eA second example is the active sites on enzymatic proteins. These act* x& u$ A: O$ ^- \+ G- |3 j3 U
as catalysts for most reactions, changing a particular substrate in an6 ^0 g* h E9 J4 S1 w- I: b
appropriate way to allow it to react more easily. Generally, the active/ k; x3 u u* q0 c2 I; m
site is found in certain specific parts of the enzyme molecule where Z. U6 h/ _1 I0 b, ]8 C
the configuration of amino acids is structured to fit the particular
9 J. x2 w8 I5 r' E# z: y. ?2 Jsubstrate, sometimes with the help of “activators” or co-enzymes. The# q( W: H6 q2 M* {
substrate molecule interlocks with the active site and in so doing
2 B! t& k$ ], C% ~2 B1 gchanges appropriately so that it no longer fits, and thus frees itself.<br/>; O* C A1 i) C0 X- v, }8 z+ T9 j8 N
2.3.2.2 Relations of Specification<br/>
, o& r! B2 W/ b6 u7 LThese determine the identity, in chemical properties, of the components
: S* {4 h/ s& `of the cell in such a way that through their interactions they
: T& v, J6 p o3 y( E& ?participate in the production of the cell. There are two main types of1 i. }& c# H$ f7 ^9 M2 n- A
structural correspondence, that among DNA, RNA, and the proteins they
5 j7 n) H( t6 d& p7 R: ^produce and that between enzymes and the substrates they catalyze.<br/>: j: Q8 I, i1 i
Protein synthesis is particularly complex because each protein is7 E) D0 o- G; f# Q
formed by linking up to twenty different amino acids in a specific
X" p1 w$ @3 P2 Q0 v9 ?combination, often containing 300 or more units in all. This requires
' h6 S) S& r6 y6 K' z( Dan RNA template molecule, tailor-made for each protein, containing) h4 V' L% G2 y# o
specific spaces for each of the amino acids in order, together with an+ G- _6 w& _% C0 C- C
enzyme and t-RNA for each acid.<br/>9 J3 Z+ [6 |& ?# h2 ?; a1 A
As already mentioned, enzymes are necessary to help most of the( n4 C4 d$ L/ i5 z/ A; v
reactions in the cell, and again, each specific reaction requires an3 `/ j5 O3 X! z3 [9 v
enzyme specific to the reaction and to the substrate involved. Hundreds
% e! U+ `) J2 aof such enzymes are needed, and all must be produced by the cell.<br/>$ [3 t$ s K- {9 f$ S
2.3.2.3 Relations of Order<br/>
i% b9 s" X6 S" n% q) {( r% GRelations of order concern the dynamics of the cell’s production0 R, a2 q( F' V- H+ i3 k
processes. Various chemicals and complex feedback loops ensure that
5 ?7 s' R% E P0 w/ {7 S5 N& tboth the rate and the sequence of the various production processes1 E# D3 X; @& f1 ]
continue autopoiesis. For instance, the production of energy through
F3 l( W# R7 Q7 z e0 Z. koxidation is controlled by the amount of phosphate and ADP (adenosine
$ Q4 ^3 t1 |- y ?3 j* Mdiphosphate) in the mitochondria. At the same time, reactions that use6 Z$ ~: Z4 v; G, F' b
energy actually produce ADP and phosphate so that, automatically, a! p: F+ |6 V- A) J) y+ D8 f% L# c
high usage of energy leads to a high production rate of these necessary
. f' `" g/ y. X9 o. T. y: {* Bsubstances.<br/>
6 D5 ~; m7 u3 |/ A M! W2.3.3 Other Possible Autopoietic Systems<br/>; f# s4 K$ G7 F' ~- h8 B
An interesting question leading from the idea of the cell as an
1 _/ z+ ?. S6 j; Q4 S4 zautopoietic system is whether or not there are other instances of
9 j6 w1 ~- u- X- {0 {, C+ Iautopoietic systems. Are multicellular organisms also autopoietic [, g; f1 [4 v9 g% R
systems? Maturana is equivocal, suggesting that organisms such as8 p$ w6 b A" E
animals and plants may be second-order autopoietic systems, with the( O. O7 t+ {/ p( d Q
components being not the cells themselves but various molecules
) @. }; `- ^) `! ?3 cproduced by the cells. On the other hand, he suggests that some
$ m. e3 u( Q, S+ Tcellular systems may not actually constitute autopoietic systems, but
6 ?3 m" c q) z m2 Hmay be merely colonies. What about a system that appears to have a. \+ L- q3 A' U; `
closed and circular organization but is not generally classified as
9 e6 R' q1 J- jliving, such as the pilot light of a gas boiler? Finally, what about" ^8 q8 O; K0 K4 O9 r# H0 x
nonphysical systems such as the autopoietic automata mentioned in
# `8 c C( f( z4 j0 lsection 2.2.1 and described more fully in section 4.4, or systems such. P$ X# q" z7 g) I/ T; K: ?# f
as a set of ideas or a society? These possibilities will be discussed9 J: L2 F7 _# a4 k" W5 X' m
in more detail in Section 3.3.<br/>; g: ^5 B/ }$ k1 n T' y
2.4.Applications of Autopoiesis in Biology and Chemistry<br/>; q1 X/ e& b4 w' i! c% _
One would have expected that, given the importance and nature of its3 G* z: f6 z8 \) p( B# y$ q
claims, autopoiesis would have had a major impact on the field of
' x6 e0 d5 k) i7 Tbiology. In fact, for many years there was a noticeable reluctance to$ U4 F" L) F+ W8 U) l
take the ideas seriously at all. In 1979, I wrote to an eminent British2 F# y B) |5 g- z9 a
biologist – Professor Steven Rose at the Open University – querying the
* a/ I4 S# u! W5 pstatus of autopoiesis. He replied to the effect that he did not wish to, u4 C3 K: t9 n
comment on autopoiesis but that Maturana was a reputable biologist. One
2 Z) w- [1 F) a2 k" S9 w0 A- \notable exception is Lynn Margulis, whose own theory, that eukaryotic$ c- z' p) G6 S, m0 _; i# m! I
cells evolved through the symbiosis of simpler units, is itself quite
6 m" V& J% h+ }" ?- M2 Icontroversial.<br/>% d2 [9 R- _. [* j. S. X( O' w' d6 k, i
However, recently interest has been growing in two areas: research into
: o5 C) f' p/ y3 `4 nthe origins of life and the creation of chemical systems that, although* h' X$ L! @! a1 Z+ ]
not living, display some of the characteristics of autopoietic% o+ V2 h$ l+ |. l' F; a
self-production. Autopoiesis has also been compared with Prigogine’s- y5 p3 o, _ x W8 l% S
dissipative structures. Varela has also pursued work on the nature of8 M7 E, w0 E3 r1 p
the immune system, viewing it as organizationally closed but not: y% n& d* v5 j3 K( w0 i! }
autopoietic. However, as this topic is very technical and not of
) R3 c, y0 W! Pprimary relevance, it cannot be pursued here.<br/>
9 P. @# ~/ Q; w$ k& g. w: w2.4.1 Minimal Cells and the Origin of Life<br/>
& `# N3 e) U7 H4 kThere are two main lines of approach to theories concerning the origin6 s/ l& Y7 f' r6 P9 G' C& f9 Z
of life on Earth. In the first approach, based on study of the enzymes0 I( H; `9 r' t3 d; M; R9 `
and genes, life is characterized as being molecular and a defining
2 f! |6 w; ^% z) L5 y! cfeature is the structure and function of the genes. In the second& ~# X+ L' M' E! s7 `3 L" R% W' \
approach, life is characterized as cellular, and its defining feature
6 H( n# f2 `2 P' f( `is metabolic functioning within the cell. However, neither approach can7 e6 H/ `8 ~7 Y' ]( d% c
really specify a standard or model for life against which important
$ h: K& L9 z+ Y& d0 { t% Nquestions may be answered. In particular, at what point did prebiotic
4 h2 h+ W* C3 a9 K: L/ wchemical systems become biotic living systems? And how could we
. `' f. s9 o2 P7 `* a, v ~recognize nonterrestrial living systems. Which might be radically
) ]8 `9 I2 \6 I; J, J. Zdifferent in structure from our own?<br/>6 Y/ j% p* `7 p8 M& [
Fleischaker proposes that the concept of autopoiesis, together with0 P, G$ |0 \; z$ w& y/ _
notions of minimal cell, can provide a sound theoretical framework to/ c% F9 S$ \6 h
tackle these questions within the second tradition mentioned above.$ e! `8 G. t. C) v
Autopoiesis clearly does aim to provide a specific and operationally
4 x8 w* s( @+ U4 s) ruseful definition of life, although Fleischaker argues that the concept
+ j1 G( R7 I* S. Cof autopoiesis does need some modification. This modification would
$ O7 h3 c: O, l- E5 G" [2 V# jrestrict “living” systems to autopoietic system in the physical domain
2 T+ E/ }: m, y7 srather that allow the possibility of nonphysical living systems, a! V4 k8 R' \' b8 h
possibility which ( as mentioned above) is left open by the formal6 h/ O) {+ t; P& p( K, ^
definition of autopoiesis. This will be discussed in Section 3.3.2<br/>
, `$ s0 d, ~7 I4 |1 \5 F' tGiven autopoiesis (or modified version) as a definition of life, the7 R* ~! K/ b5 \4 R, g# L3 H1 R7 {
next step in theorizing about the origin of life is to consider how an
% Z% o+ s- J( nelementary autopoietic system might have formed. Note that autopoiesis. o' d) C3 x3 g) @0 E3 o4 A; p
is all or nothing. A self-producing system either exists and produces
2 w5 d+ X/ T# g1 J8 f5 u( g. q" Ditself or it does not – there can be no halfway stage. This leads to
$ a, T3 J" j% e2 }5 Ethe idea of a theoretical “minimal” cell which could plausibly emerge,
5 ? F/ I$ A6 O' _given the early conditions on earth. In fact, Fleischaker considers
4 v$ E1 f* s# p. F% k! Q Bthree different characterizations of minimal cells: a minimal cell
1 S" `1 r2 q6 Irepresentative of the evolved life forms that we know today; a minimal
1 [' i2 F& ^9 Dcell that would characterize both terrestrial and nonterrestrial life8 l& S" t+ O* t, C3 G
regardless of its constituents.<br/>9 ^6 t& Y% x7 [* u$ Q9 U& S) S
About the last, little can be put forward beyond the six-point! Z0 V9 m; E9 P5 F8 p$ B4 P2 u
autopoietic characteristics in the physical space; to be more specific
2 F1 W U N4 c+ F6 W( uwould constrain the possibilities unnecessarily. On the other hand, we- v" z9 Y4 }& i, L$ H# J6 J9 q
can be quite specific about a modern-day cell. Such a cell could be( u2 P4 z/ _+ i/ g( j* W e- C
described as “a volume of cytoplasmic solvent capable of DNA-cycled,5 w+ ~% _% A: w- T0 W' I' h5 z7 L
ATP-driven and enzyme-mediated metabolism enclosed within a* a' U$ Y, l2 l7 I$ L& f
phosphor-lipoprotein membrane capable of energy transduction”, This
1 P% B" H: O7 ?3 d: Hgeneralized specification can cover both prokaryotes (bacterial) and
1 U5 q" S( v4 x/ e% a ceukaryotes (algal, fungal, animal, and plant cells) even though there7 j. ?+ Z- i9 G. `5 L: s
are important differences in their operation.<br/>
, g& n1 t$ n2 K4 p5 ?' wThe most interesting minimal cell scenario concerns the origin of life.) j/ S% y' N$ k: y! M0 l; q
The first cell need be only a very basic cell without the later
% O- x0 \; s4 ?' } h" x0 U" P uelaborations such as enzymes. Fleischaker suggests that such a cell; {# k8 m. W D6 t3 F0 Z
must exhibit a number of operations (Fig.2.4):<br/>- {2 ]6 A& F+ U' I9 p
1、The cell must demonstrate the formation and maintenance of a boundary( B0 z" b& ~1 s: S
structure that creates a hospitable inner environment and allows
x" B/ U1 s$ l& Q2 Sselective permeability for incoming and outgoing molecules and ions.4 m0 A: o8 [1 h2 ~% X, b& K; Z
The lipid bilayer found in contemporary cells is a good possibility
* G: ?, i" O9 U5 v) b3 dsince the hydropholic nature of lipid molecules leads them to form$ H( u9 g& H7 Z) _! a. J
closed spheres in order to avoid contact with water. Lipid bilayers are9 ~, y/ X. U0 v
also permeable in certain ways – for example, to flows of protons or
( K# E0 L3 S- Y4 o9 Y1 v+ zsodium atoms – without the need for the complex enzymes prevalent in
, d' O, p1 R! O* A$ \9 s acontemporary cells.<br/>
6 ^) h* Q8 K& i7 U6 F( ]2. The cell must also demonstrate some form of active energy6 e X& g% c9 C6 I, A
transduction to maintain it away from entropic chemical equilibrium.4 x4 V" E/ h# I. c2 ~7 i
One possibility is an early form of photopigment system driven by
) ?- R9 A4 T! ~light. Pigment molecules would become embedded in the membrane and act
. S. V% z6 `! U; c4 bas proton pumps, leading to the concentration of variety of raw" r" r o6 @/ S# R5 S I5 _
material in the cell.<br/>
9 m! d/ t" E( b3. The cell would also need to transport and transform material: s% h* J1 _8 r0 f
elements and use these in the production of the cell’s components and
: H( y: t6 v2 Qits boundary. A possible start in this direction would be the import of% U1 t7 W* C) z% V! j! ?5 c/ y1 R' ^
carbon dioxide and the physio-chemical transformation of its carbon and
% U" E- j7 H! a) Qoxygen through light-driven carbon fixation.<br/>
4 L7 Y+ y! w% r' ?5 x+ S8 iWhat is important is not the particular mechanisms for any of these
* C5 \) ~% D7 Z0 ?/ Tgeneral operations but that whichever mechanisms are postulated, all
) m) M( A! e; U$ r( Moperations need to be part of a continuous network to form a dynamic,4 x9 O1 Y/ f6 g- g
self-producing whole.<br/>
2 q+ G$ n) W8 M: c: I; h0 D. {2.4.2 Chemical Autopoiesis<br/>, ?, O9 S( g3 c5 y* O9 c- ~! N
Beyond theoretical constructs of minimal cells, it is also interesting
8 Q1 _* ]# H' O2 }3 b: j+ \& B* Zto look at attempts to identify or create chemical systems based on
' b& J, X! Y+ X# M8 jautopoietic criteria, and to consider whether or not these are living.& _5 s5 ~. N0 H$ B" S3 Y: w7 L
We shall look at three examples: autocatalytic processes, osmotic
& s! U+ E8 o: m3 ^% o i, Pgrowth, and self-replicating micelles.<br/>
$ A& |* R& D0 ~3 o% b2.4.2.1. Autocatalytic Reactions<br/>
, F* y* U# _& o' H0 v$ O# PA catalyst is a molecular substance whose presence is necessary for the: C5 g' c! B6 r' g! ^ V3 x
occurrence of a particular chemical reaction, or which speeds the
/ D" Q9 U9 R% ?% B1 creaction up, but which is not changed by the reaction. The complex1 S0 s! }( I1 B+ r6 v3 h) D! Y
productions of contemporary cells (as opposed to cells that may have
) |4 A+ k. b0 y- v/ R4 Xexisted at the origin of life) require many catalysts, and this is one
0 q8 ^: Q) \1 Uof the main functions of the enzymes. An autocatalytic process is one' V4 N, G6 y- T$ c+ r0 L
in which the specific catalysts required are themselves produced as
" J& h- ~3 o* j) mby-products of the reactions. The process thus self-catalyzes. An
. \- l8 B f, V1 R0 ]example is RNA itself which, in certain circumstances, can form a
2 f" ~1 M$ E& S Vcomplex surface that acts like an enzyme in reaction with other RNA
+ h5 }8 t0 X( o+ _/ R' Gmolecules (Alberts et al.) Kauffman has a detailed discussion within
: L$ ~5 {- u1 B0 K6 hthe context of complexity theory.<br/>) ~; ~1 { r) N( J. E
Although this process can be described as a self-referring interaction,, `3 m y; t6 _" s z
the system does not qualify as autopoietic because it does not produce2 f9 @1 v) a$ J' X
its own boundary components and thus cannot establish itself as an7 E: O5 V" N3 d' o( f: x- C
autonomous operational entity (Maturana and Varela). Complex,* d2 h* x1 P+ p5 @4 X
interdependent chemical processes abound in nature, but they are not
* K% J8 R( p1 r% X+ r4 N- sautopoietic unless they form self-bounded unities that embody the
, z+ W/ r7 d1 y0 s! Z$ eautopoietic organization.<br/>
( d9 Q* g4 f' U$ Q# f2.4.2.2 Osmotic Growth<br/># \7 ~' I8 s- j) F5 x! P
Zeleny and Hufford have suggested that a particular form of osmotic: ]( I" K* B' X
growth, studied by Leduc, can be seen as autopoietic. The growth is$ {& F6 f. A* _( S- V. l7 s( [
precipitation of inorganic salt that expands and forms a permeable
& `/ G1 q1 {, { @osmotic boundary. This can be demonstrated by putting calcium chloride
! ?0 b+ q. f) f8 D, n8 g: [+ rinto a saturated solution of sodium phosphate. Interaction of the
1 Y5 V) ]3 l+ X6 Fcalcium and phosphate ions leads to the precipitation of calcium! o$ d* M3 D0 t E2 h- e i1 }
phosphate in a thin boundary layer. This layer then separates the% X0 [" M- {' |
phosphate from the calcium, water enters through the boundary by1 _$ ]# U2 f* l- `
osmosis, and the increased internal pressure breaks the precipitated7 F" w4 a) C+ m: {9 n, J
calcium phosphate. This break allows further contact between the
% O' ?' l/ P' E& h% o4 r3 h* A- Rinternal calcium and the external phosphate, leading to further9 p F" F \% K+ X( G) m4 w
precipitation. Thus the precipitated layer grows.<br/>
3 D- \% e; u. {' R# u; D! s6 \% vZeleny and Hufford argue that this system fulfills the six autopoietic criteria:<br/>
! K7 K" H3 A# x6 G* G+ v1. It is distinguishable entity because of its precipitate boundary.<br/>
3 h+ N' Z/ m* @2. It is analyzable into components such as the calcium phosphate boundary and the calcium chloride.<br/>" z6 C+ q7 y! P0 W7 P7 {* U
3. It follows mechanistic laws.<br/>* g+ I9 w: |1 A6 t" |& y
4. The boundary components (calcium phosphate) aggregate because of their preferred neighborhood relations.<br/>
1 i$ o8 s+ u$ l0 E$ W1 ]7 r3 L5. The boundary components are formed by the interaction of internal9 G. q1 s s' y6 j! G% R
and external components following osmosis through the membrane.<br/>" q4 _8 z2 u+ X4 z8 U
6. The components (calcium chloride) are not produced by the cell but
0 g5 I: Q9 ?; e, o" W. vare permanent constituent components in the production of other
9 Y' i# d4 D4 Z l9 C/ o9 ~components (the precipitate)<br/>
5 r# I( g& S! MThis hypothesis does cause problems, as Leduc’s system is clearly
1 i4 S. `7 C. r# s( {inorganic and not what would be called living. If it is accepted that# I1 i9 s6 ]( k7 \! D: T L
the system does properly fulfill the criteria of autopoiesis, i.e.,% _ }* p7 k& _# ~( a
that it is an autopoietic system as currently defined, then either we
" Q) e3 r) e9 v, l3 O& @$ d) D4 emust expand our concept of living or accept that autopoiesis is in need
% u; r0 \: J: ^1 L$ a4 K& Yof redefinition to exclude such examples. In fact, it is debatable& |+ E2 o: \! w
whether or not this osmotic growth does correctly fulfill the six; |5 R# m2 f4 ? H7 ]
criteria. It certainly meets the first three, but it is not clear that9 G0 ]2 O. ^, E
it is a dynamic network of processes of production.<br/>
# U; `/ t i- X- r, A/ uAs for the fourth criterion, the precipitate that forms the boundary is
4 \6 I6 D' `) B: Uunlike a cell membrane. It is static and inactive, more like a stone
6 z* Y _3 Z" l( c( owall than an active membrane. It is not formed through “preferential [+ {( x8 W4 T3 H5 S% O7 L
neighborhood interactions”; in fact, once formed, it does not interact
" R. ~1 `' c. cat all. Considering the fifth criterion, the boundary components are9 u, N) C9 X& ?% z# l
not continuously produced by the internal processes of production.
2 m0 k& a$ s I& z. g; ^0 ?Rather, a split or rupture occurs and more boundary is precipitated at8 g2 Z+ k) C+ ?
the split through the interaction of internal and external chemicals.
1 E! o- [) {1 V$ V& g8 K( q3 GIt is only because of, and at, the rupture that new boundary is, ~3 }- {; Y( f4 l) V
produced. Finally, chloride, which is introduced artificially at the0 u7 U2 R# N# B+ u" u- B! @
beginning, is not produced by the system, and eventually runs out.<br/>( A/ Y1 m7 }# t+ J: w
2.4.2.3 Self-replicating Micelles<br/>
. L0 z" M" }1 {* ^: z( R! Z5 ]. zAn approach with more potential, currently being researched by Bachmann2 X1 |2 q2 \% p% B
and colleagues, was first proposed by Luisi. It has been discussed by
* |) G3 ]$ e m- y% TMaddox and Hadlington. A micelle is a small droplet of an organic4 ~: P) ~+ ]9 L h3 V' v
chemical such as alcohol stabilized in an aqueous solution by a
; i9 w) k* I- qboundary or “surfactant” A reverse micelle is a droplet of water
! Z/ C0 D! V2 k/ Wsimilarly stabilized in an organic solvent. Chemical reactions occur% v- ~+ M9 V( n6 j& C
within the micelle, producing more of the boundary surfactant.
} t+ H0 c( L6 aEventually, this leads to the splitting of the micelle and the
J& U- y1 O( e. Wgeneration of a new one, a process of self-replication. Experiments# Y( n H4 J6 F2 V* M1 Z8 `3 u
have been carried out with both ordinary and reverse micelles and with
7 c* c- [, j# {! ~# O4 pan enzymatically driven system.<br/>4 J1 _2 m1 S" ^
In the reverse micelle experiments, the water droplets contain
8 c* a0 B4 |$ t5 {dissolved lithium hydroxide, one of the surfactants is sodium: H) @& z# Y; [* X2 l( q; J2 b
octanoate, and the other is 1-octanol, which is also a solvent. The& [* t9 Q f% j4 T
other solvent is isooctane. The main reaction is one in which the
: v( F1 K" R+ T6 b1 E# }) Hcomponents of the boundary are themselves produced at the boundary.2 n V! P0 s6 E6 [+ r
Octyl octanoate is hydrolyzed using the lithium as a catalyst. This. p3 W6 X3 B8 }, [
produces both the surfactants (sodium octanoate and 1-octanol). Since' W l0 L% X! Z) U5 u
the lithium hydroxide is insoluble in the organic solvent, it remains: S7 l" |+ D4 F0 f! Y
within the water micelle, thus confining the reaction to the boundary
3 B, J, L, l' `+ e: tlayer. Once the system is initiated, large numbers of new micelles are+ U+ T) S/ }$ _8 G
produced, although the average size of the micelles decreases.<br/>
) R$ y9 O) G8 L$ _It is not clear that these systems could yet be called autopoietic.
0 z# U% q0 m {) F# a! T1 J1 g7 E1 kFirst, the raw materials(the water-lithium mixture or the enzyme
; Q3 L: w9 m# q1 N5 O' V* j7 t! G. gcatalyst) are not produced within the system. This limits the amount of
* ]7 Y& J+ `5 v$ ~1 H- E& H+ j" h3 S* ^replication which can occur; the system eventually stops. Even if these" l4 o, R( R5 q, ]0 q4 w% P
materials could be added on a regular basis, the system would still not
$ {3 J. \; d3 \8 W& M' P* \be self-producing. Second, the single-layer surfactant does not allow5 }( H0 s2 K3 y
transport of raw materials into the micelle. For this to happen, a
3 J' F2 U2 J2 I" P. }8 odouble-layer boundary would be necessary, as exists in actual cell3 C8 h% O% U- F5 `, A$ V, D
membranes. Moreover, the researchers themselves, and seem most
Y5 Y, l: o# {; e5 @$ ?$ m- h3 kinterested in the fact that the micelles reproduce themselves, and seem
8 n2 b6 q, {# R- |3 c; ]$ ito identify this as autopoietic. However, reproduction of the whole is/ s7 h7 R% S+ \7 K
quite secondary to the autopoietic process of self-production of" ^! }& A% N8 v. C3 A: D
components. Nevertheless, this does represent an interesting step
" f( x9 {8 B! n# Y a0 vtoward generating real autopoietic systems. |
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