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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/>
: r, o& S$ l4 R/ e! A6 V, @7 ]The fundamental question Maturana and Varela set out to answer is: what& ?0 p" l* _& n/ C
distinguishes entities or systems that we would call living from other$ N$ p9 }$ y' i% {6 l/ L
systems, apparently equally complex, which we would not? How, for
6 z' v' U, E/ Lexample, should a Martian distinguish between a horse and a car? This
, g' ^: }" h& j( _7 C% {7 Bis an example that Monod (1974, p. 19) uses in addressing the similar
& a( N5 T) l0 o7 ]but not identical question of distinguishing between natural and( h' Q1 k8 E2 k$ I, }5 y5 s; U) J) U
artificial systems.<br/>
- }' J% e: s5 E2 i) q1 q4 mThis has always been a problem for biologists, who have developed a6 @9 K) h" `) _
variety of answers. First came vitalism (Bergson, 1911; Driesch, 1908),( P# |# L" s% S* f, a/ c
which held that there is some substance or force or principle, as yet( h2 m+ {7 X7 @' R* h
unobserved, which must account for the peculiar characteristics of- {2 b6 |& v3 ]0 ~
life. Then system theory, with the development of concepts such as
* H( P1 N G m* E3 Sfeedback, homeostasis, and open systems, paved the way for explanations N2 q Z. A* ?5 c
of the complex, goal-seeking behavior of organisms in purely
7 z3 ]4 {6 j' I5 T6 amechanistic term ( for example, Cannon, 1939; Priban, 1968). While this
3 m4 u% z& u. q7 t6 u% e' `was a significant advance, such mechanisms could equally well be built4 h) H% W' r% x1 j7 G5 B2 J( b# ~
into simple machines that would never qualify as living organisms.<br/>
: t, b* O3 ]3 r, h5 L$ pA third approach, the most common recently, is to specify a list of1 d# m T0 Z( v7 l$ }2 p. q
necessary characteristics that any living organism must have – such as& Y1 g7 x% Z$ w: P& W [
reproductive ability, information-processing capabilities, carbon-based% f5 D6 ~, U/ F: j; [" {4 a( w
chemistry, and nucleic acids (see, for example, Miller, 1978; Bunge,7 @) C4 M" W6 {$ S
1979). The first difficulty with this approach is that it is entirely: j) d% |; k. o; p
descriptive and not in any real sense explanatory. It works by
7 f' y) k5 S$ p( robserving systems that are accepted as living and noting some of their
4 l! [6 I t2 W$ Fcommon characteristics. However, this tactic assumes precisely that
2 n, U( p& |3 S1 T5 zwhich is in need of explanation – the distinction between the living: j5 t6 t7 c# ^" T6 F4 V
and the nonliving. The approach fails to define the characteristics4 g: y& D+ q3 c* V, G* h) T6 p6 K
particular to living systems alone or to give any explanation as to how" o3 L7 m' I3 y4 q7 d2 h: }% u- w; q
such characteristics might generate the observed phenomena. Second,
" C5 a/ v% ^1 |/ dthere is, inevitably, always a lack of agreement about the contents of' q; ]& W. [% k) p' G* U
such lists. Any two lists will contain different characteristics, and
8 v% L2 X# Q& ?* M7 G& c4 vit is difficult to prove that every feature in a list is really
2 C/ a, Y( ]" G% knecessary or that the list is actually complete.<br/>- h/ G. R. I) d7 l% D; b1 c
Maturana’s and Varela’s work is based on a number of fundamental3 [, e* ^2 G5 L5 s5 Y
observations about the nature of living systems. They will be: b7 F/ Y( _6 I) R( o3 H! Y3 a
introduced briefly here but discussed in more detail in later chapters.<br/># O( g, Z* ?$ b$ H0 ?; k
1. Somewhat in opposition to current trends that focus on the species
, B7 v. F9 O zor the genes (Dawkins,1978), Maturana and Varela pick out the single,
) k9 d8 s' A4 Sbiological individual (for instance, a single celled creature such as
( y9 z6 J& m! J+ ~an amoeba) as the central example of a living system. One essential; y; e! G8 {4 N! g7 W7 D
feature of such living entities is their individual autonomy. Although, v0 L& `2 W8 M- H4 [7 v8 M( p3 p
they are part of organisms, populations, and species and are affected
0 T2 K( l% Y% zby their environment, individuals are bounded, self-defined entities.<br/>/ h6 r3 w7 W$ Y" Z2 n& `
2. Living systems operate in an essentially mechanistic way. They
5 T0 k+ i, k$ b% b s, ]8 n- \consist of particular components that have various properties and8 ^9 _. }$ w6 Q# _( U9 X
interactions. The overall behavior of the whole is generated purely by5 P% T/ H- [ V
these components and their properties through the interactions of
o8 B. b4 D3 v4 t0 }* d) uneighboring elements. Thus any explanation of living systems must be a
% o0 \9 I, ]( t8 y$ [) X# ypurely mechanistic one.<br/>
& ?. i$ Q5 M) g5 @- {3. All explanations or descriptions are made by observers (i.e.,
+ d( u" B/ a. Y/ cpeople) who are external to the system. One must not confuse that which" p7 Y: m1 |0 p# I
pertains to the observer with that which pertains to the observed.5 h: |% e% J& X2 b' N& Y; g9 _
Observers can perceive both an entity and its environment and see how! g* g+ l6 F3 W3 O( Y& ^
the two relate to each other. Components within an entity, however,3 m F& w- S9 U( r8 F) n- w
cannot do this, but act purely in response to other components.<br/>' L1 a+ X7 z; D( w& c; P
4. The last two lead to the idea that any explanation of living systems
" Q: n. N) M7 H/ M+ K2 rshould be nonteleological, i.e., it should not have recourse to ideas
5 b& [4 |- B+ Mof function and purpose. The observable phenomena of living systems9 U6 E. Q4 }0 i
result purely from the interactions of neighboring internal components.- }7 l$ z; c, F( u, w, U: ~
The observation that certain parts appear to have a function with
! y5 ?. |1 k, m% E/ e; o% B* B& \regard to the whole can be made only by an observer who can interact- _( u0 i% v8 E+ n5 j4 s
with both the component and with the whole and describe the relation of; q1 J# Z# ]# c0 H7 @; e4 |
the two.<br/>
! \- a+ e) l1 Y1 ]$ V9 h <br/>) O0 _* B% p/ @9 J
To explain the nature of living systems, Maturana and Varela focus on a0 o! i8 y5 A0 F1 V2 o
single basic example – the individual, living cell. Briefly, a cell
: Q. ?5 t2 W" R# J/ mconsists of cell membrane or boundary enclosing various structures such$ O! \) m; N( T4 y% c; X0 S) I
as nucleus, mitochondria, and lysosomes as well as many (and often
9 k+ I2 K4 s" ]" K! P acomplex) molecules produced from within. These structures are in! x/ S) t7 k5 ^
constant chemical interplay both with each other and, in the case of
4 R0 c; T: V/ K5 v' ]the membrane, with their external medium. It is a dynamic, integrated
2 M' d* _9 Q, ?& \- s% hchemical network of incredible sophistication (see for example Alberts. J/ I# O: a' X5 H+ d
et al.,1989; Raven and Johnson,1991).<br/>
2 v6 @* @1 q# |: B8 T. pWhat is it that characterizes this as an autonomous, dynamic, living% Z0 }; Z# q6 C
whole? What distinguishes it from machine such as a chemical factory8 Z7 Y( x! `3 w* O
which also consists of complex components and interacting processes of( `( _$ j K) A1 C
production forming an organized whole? It can not be to do with any
) S8 w0 A8 N# o' G: tfunctions or purposes that any single cell might fulfill in a larger" P. q* w& O: f: u4 S2 X
multi-cellular organism since there are single-cellular organisms that4 K* D# ~) J4 X2 G+ q% f
survive by themselves. Nor can it explained in a reductionist way( W d6 q4 x$ G. T6 v" J5 C3 t! W* E
through particular structures or components of the cell such as the, L! |$ s q8 b. r0 d! F
nucleus or DNA/RNA. The difference must stem from the way of the parts
( v6 P/ F B9 J. a6 N9 t3 k9 [are organized as a whole. To understand Maturana and Varela’s answer,2 p! P/ b6 T7 Q/ N1 d0 }
we need to look at two related questions – what is it that the cell+ G. E. |2 {, S; A% K5 Y# o
does, that is what is it the cell produces? And what is it that/ l4 n+ N& p9 o6 w% b! E# G
produces the cell? By this I mean the cell itself rather than the
v/ X+ ?3 f* y* ^results of their reproduction.<br/>
+ C% I/ h& u4 M. C) l [7 gWhat does a cell do? This will be looked at in detail in Section 2.3 @ k C1 n! w9 B. V/ Z( D
but, in essence, it produces many complex and simple substances which F1 @, ]/ W8 h/ M' ?
remain in the cell (become of the cell membrane) and participate in
* N0 u- M+ U: z k7 q! V2 i( u7 z) ^, zthose very same production processes. Some molecules are excreted from
& {1 O+ s7 I C, M: r: Tthe cell, through the membrane, as waste. What is it that produces the
& r0 |$ U- E, r6 P: }0 c' c% Z8 |components of the cell? With the help of some basic chemicals imported
* ] s& z* l1 b. c; g9 m2 ^from its medium, the cell produces its own constituents. So a cell
4 l3 {) f& \( zproduces its own components, which are therefore what produces it in a3 G, n0 @- I4 W( o: i& F
circular, ongoing process (Fig. 2.1)<br/>
/ \1 q* C2 o6 @. h+ U; }It produces, and is produced by, nothing other than itself. This simple
1 [3 J- Q1 |4 o/ S$ |6 xidea is all that is meant by autopoiesis. The word means
+ y$ I6 ], R+ s( l3 f R, M, b3 f“self-producing” and that is what the cell does: it continually7 y1 A5 O3 G; W& Q) g
produces itself. Living systems are autopoietic – they are organized in
# E) n# B' f- |5 Lsuch a way that their processes produce the very components necessary
. u* V4 a' [! `% m+ K2 s: Xfor the continuance of these processes. Systems which do not produce; F( Y3 c }! f
themselves are called allopoietic, meaning “other-producing” – for" G1 _- E, J4 F
example, a river or a crystal. Maturana and Varela also refer to
( y0 C' J( m7 |6 g1 M; Q6 Shuman-created systems as heteropoietic. An exemple is a chemical
9 b! E5 F8 E7 m* g: Y- Jfactory. Superficially, this is similar to cell, but it produces: E/ I" l3 I" Q1 o$ q
chemicals that are used elsewhere, and is itself produced or maintained
6 j7 J& D/ S% Q. oby other systems. It is not self-producing.<br/>! b- i7 F' V; {5 j+ A5 a
At first sight this may seem an almost trivial idea, yet further contemplation reviews how significance it is. For example:<br/>
6 ~6 R V7 {7 {% y# i1. Imagine try to build autopoietic machine. Save for energy and some# X, H# Y2 g5 ]
basic chemicals, everything within it would itself have to be produced
& o2 j% V/ k. B7 T/ P5 v( bby the machine itself. So, there would have to be machines to produce( E/ m$ q, A- [* C
the various components. Of course, these machines themselves would have$ j5 g: @7 e) J: I/ U# A
to be produced, maintained, and repaired by yet more machines, and so7 s/ f2 } M0 M V3 g
on, all within the same single entity. The machine would soon encompass$ f! _: J2 T' i3 ?$ I
the whole economy.<br/>
: T7 X2 ~- I8 E( n* B! e8 d8 T2. Suppose that you succeed. Then surely what you have created would be# }0 P4 G+ j% L* J' a/ a8 i: r0 R
autonomous and independent. It would have the ability to construct and
, `5 T# m1 i, b9 v% j) Y1 Breconstruct itself, and would, in a very real sense, be no longer) x$ k( F, ?' U }
controlled by us, its creators. Would it not seem appropriate to call0 N S9 |6 S3 {2 Z! n4 Y
it living?<br/>& H) c4 d- z: D& F( [
3. As life on earth originated from a sea of chemicals, a cell in which
& K( m6 w# m7 i# X- Z' ca set of chemicals interacted such that the cell created and re-created
9 v5 ~0 [! T4 f" zits own constituents would generate a stable, self-defined entity with6 r1 P p; D- J4 w6 O/ \/ Z
a vastly enhanced chance of future development. This indeed is the
* L p, R2 X/ U2 d. s Z, ?basis for current research, to be described in section 2.4.1<br/>
& U- Y# g+ a# L/ s8 M% y4. What of death? If, for some reason, either internal or external, any( T/ D! G6 ]% r5 c3 @
part of the self-production process breaks down, then there is nothing
9 s4 l$ K# T' d. f9 N2 }/ Telse to produce the necessary components and the whole process falls
1 j9 Q0 i; U& b' k! A/ ], x {- Fapart. Autopoiesis is all or nothing – all the processes must be4 U5 P9 {0 g$ t1 `. q9 y$ X
working, or the systems disintegrates.<br/>! t# y- G$ H- U# }5 S5 O$ J8 S) ?
This, then, is the central idea of autopoiesis: a living system is one
$ M7 r* }( d0 p# Z5 g0 uorganized in such a way that all its components and processes jointly
2 [& P8 r( Z$ M5 K! l7 b* vproduce those self-producing entity. This concept has nearly been
6 p6 \5 q1 V. w6 c" Pgrasped by other biologists, as the quotation from Rose at the start of
) [ ^0 A8 X- ]this chapter shows. But Maturana and Varela were the first to coin a0 C7 X: j* {* _. v& c& r" D, D
word for this life-generating mechanism, to set out criteria for it
: D$ J5 F1 W& z, b: q% Z(Varela et al., 1974), and to explore its consequences in a rigorous# k0 W0 Y2 n, F+ Z4 D6 \
way.<br/>
_ E- C' b9 t+ u, m# lConsidering the derivation of the word itself, Maturana explains that6 I4 P% w7 I9 O
he had the main idea of a circular, self-referring organization without
2 F$ _ b% D9 M& N$ q/ ]/ p& e! D, Hthe term autopoiesis. In fact, biology of cognition, the first major
: c6 ~: _5 o! uexposition of the idea, does not use it. Maturana coined the term in! e. J, s1 _3 F S# E
relation to the distinction between praxis (the path of arms, or$ |1 {8 z% q$ p2 c
action) and poiesis (the path of letters, or creation). However, it is
8 W4 l' z: F7 `: F, Iinteresting to see how closely Maturana’s usage of auto- and
: s9 S- R: U/ j9 n: C( \3 wallopoiesis is actually foreshadowed by the German phenomenological' w( j5 R( b8 f' P, K3 X' O
philosopher Martin Heidegger. In the quotation at the start of Chapter
* E& p- {$ k' D9 } n6 j$ H1, Heidegger uses the term poiesis as a bringing-forth and draws the
6 a! P0 @) Z7 M+ B" _9 Rcontrast between the self-production (heautoi) of nature and the
$ M1 z# X; ^* P3 w8 cother-production (alloi) that humans do. Heidegger’s relevance to$ U$ D) U+ t z) C3 p L/ ^
Maturana’s work will be considered further in Section 7.5.2<br/>
# F9 z$ R9 ?2 O- R3 K( ]2.2 Formal Specification of Autopoiesis<br/># K+ `2 b; m3 m0 n+ ~* W8 R+ b
Now that I have sketched the idea in general terms, this section will
$ W! p1 D2 V. S8 }+ v( U! Udescribe in more detail Maturana’s and Varela’s specification and; k7 U- K: y/ t
vocabulary.<br/>0 a# |4 H6 Q8 T+ T. K( |0 ]
We begin from the observation that all descriptions and explanations6 l' R, p' p8 b- M+ K1 M! S
are made by observers who distinguish an entity or phenomenon from the
- X' f! E6 ]& u5 X$ g. `- I( zgeneral background. Such descriptions always depend in part on the' I; n8 I9 u0 n D8 d1 t; o7 N% \8 T
choices and processes of the observer and may or may not correspond to B4 x4 R' e" ~4 R8 @4 o* G& E4 f
the actual domain of the observed entity. That which is distinguished
) |0 ]' x1 H, r2 U7 P0 u& Lby an observer, Maturana calls a unity, that is, a whole distinguished
! Y1 f" u0 w: V I2 Afrom a background. In making the distinction, the properties which
- A, m! D3 a; w/ Aspecify the unity as a whole are established by the observer. For3 O& ?9 @) I |0 T5 h
example, in calling something “a car,” certain basic attributes or
; P6 H0 L/ N+ \) C! Wdefining features (it is mobile, carries people, is steerable) are0 w5 g5 s3 A6 c
specified. An observer may go further and analyze a unity into7 Q+ T9 U& t# y6 }) z3 @% r2 H) ?: R
components and their relations. There are different, equally valid,
- X) k& U/ ?4 S# `8 D! n1 `- x1 [$ mways in which this can be done. The result will be a description of a
% V9 Z& C9 o- @1 @- @( @composite unity of components and the organization which combines its$ j' k' {& c3 I l3 e2 I4 ~
components together into a whole.<br/>
8 ~& j+ W! ~1 Y. i( [! c+ a0 x1 OMaturana and Varela draw an important distinction between the organization of a unity and its structure:<br/>
$ x+ B; O2 W$ }3 }7 K[Organization]refers to the relations between components that define2 W2 Y0 p8 @: U" ]) \! o% C! A* G& W
and specify a system as a composite unity of a particular class, and7 _1 ^$ P0 P) W- W; t, ^
determine its properties as such a unity … by specifying a domain in& |+ o s& d6 r9 B8 P
which it can interact as an unanalyzable whole endowed with9 v2 a% j, A, |0 |- j5 ]% j/ o8 @9 Z
constitutive properties.<br/>
! j' o7 ~5 U/ Z" `[Structure] refers to the actual components and the actual relations: W- H; K2 z! n* t5 |
that these must satisfy in their participation in the constitution of a: |$ m5 A4 w: W; J
given composite unity [and] determines the space in which it exists as
( x4 i5 c6 X( aa composite unity that can be perturbed through the interactions of its7 \1 @! d/ h# X9 x- I7 |$ Z
components, but the structure does not determine its properties as a
3 `+ O$ K$ Q. yunity.<br/>
8 \& g: ~2 m) \% _* c$ FMaturana (1978, p. 32)<br/>
# b" u( d2 }3 i! V( f1 kThe organization consists of the relations among components and the, ?# j. l9 c" F0 D
necessary properties of the components that characterize or define the2 a8 N4 ?+ p" k$ ?- x) j
unity in general as belonging to a particular type or class. This
. i5 F/ S( N* e* Q& p: Ldetermines its properties as a whole. At its most simple, we can$ ?. f$ F; [) f) \+ q6 B5 n& ^- q3 {
illustrate this distinction with the concept of a square. A square is
' x' U) k3 q/ @. T4 p8 [defined in terms of the (spatial) relations between components – a& D3 P# D; q) R& j
figure with four equal sides, connected together at right angles. This
6 y+ ]% T- U1 s; A6 P) ?/ h& Eis its organization. Any particular physically existing square is a) v* r- [1 _$ H- c+ [
particular structure that embodies these relations. Another example is
* ]7 V, H3 k, ~7 [* g3 e9 u4 d0 Ja an airplane, which may be defined by describing necessary components
' M1 R) b9 H( ~+ p5 tsuch as wings, engines, controls, brakes, seating, and the relations
4 `. d3 v0 a0 C9 Pbetween them allowing it to fly. If a unity has such an organization,
1 l7 A! S5 P9 l/ {9 ^; bthen it may be identified as a plane since this particular organizatio+ l$ E0 O6 r- y+ N) _' R% E
would produce the properties we expect in a plane as a whole.6 M) d8 Q' k; g2 F$ \
Structure, on the other hand, describes the actual components and; b8 W I1 [) D. l2 Q% c
actual relations of a particular real example of any such entity, such
9 k) ^! f9 Z9 Yas the Boeing 757 I board at the airport.<br/>7 x7 F$ H" }% t' k* Y
This is a rather unusual use of the term structure (Andrew, 1979).
2 Y) g& o% C( q0 p" CGenerally, in the description of a system, structure is contrasted with, z% L. I# _) d! v
process to refer to those parts of the system which change only slowly;+ @, f6 e3 M# O4 q% a
structure and organization would be almost interchangeable. Here,
& x; k5 M8 Y- V$ d' B+ E/ E9 s Ehowever, structure refers to both the static and dynamic elements. The9 O. u1 I! w/ i& t. H
distinction between structure and organization is between the reality
0 X, f1 m2 n0 }& H0 V* z7 r9 {: Nof an actual example and the abstract generality lying behind all such
, Y8 w" ]/ p; P# Oexamples. This is strongly reminiscent of the philosophy of classic; o. W. a# k) Z3 Q
structuralism in which an empirical surface “structure” of events is
' ~. w. u% @, Nrelated to an unobservable deep structure (“organization”) of basic
9 E6 \8 ^- x3 ^3 j F$ D& hrelationships which generate the surface.<br/>7 i) _" o" O2 J8 _0 I3 S# U
An existing, composite unity, therefore, has both a structure and an5 W/ {+ h* s4 Y4 k, a; I* X6 o
organization. There are many different structures that can realize the
2 x/ d; L3 m5 f0 Ksame organization, and the structure will have many properties and
( t4 ]8 \6 B4 W+ q& ?2 a) Yrelations not specified by the organization and essentially irrelevant$ C' e/ K7 R, F
to it – for example, the shape, color, size, and material of a
% V3 X# K; j5 K$ ^! Y* J, lparticular airplane. Moreover, the structure can change or be changed
( X8 p, U, g2 p2 }' fwithout necessarily altering the organization. For example, as the
1 G! Y% P3 x7 H) _! i" K5 b) J( e' tplane ages, has new parts installed, and gets repainted it still) @; G: ~8 \: {
maintains its identity as a plane because its underlying organization3 m |6 t! F: w2 {' d/ q* ~1 M
has not changed. Some changes, however, will not be compatible with the
- s' M+ B7 F; h5 Y/ g: G; T5 Zmaintenance of the organization – for example, a crash which converts
7 @% Q7 P7 P4 z2 Fthe plane into a wreck.<br/>
9 O9 M. h/ W* q- A! \The essential distinction between organization and structure is between7 r( }' ]3 ^0 V9 d! j; N- s
a whole and its parts. Only the plane as a whole can fly – this is its
; ^$ Z, e2 p: A6 cconstitutive property as a unity, its organization. Its parts, however,2 ~9 F, `0 L) }" n" G! |6 c
can interact in their own domains depending on all their properties,
0 ]/ P! @1 {4 {2 x4 sbut they do so only as individual components. Sucking in a bird can
, X S, g# x( D+ z; H2 Kstop an engine; a short circuit can damage the controls. These are
2 g2 y% c- a% ~* t4 \: |perturbations of the structure, which may affect the whole and lead to
; J6 U' e8 d' g. j. u3 ia loss of organization or which may be compensable, in which can the* O2 }+ O& I0 U p
plane is still able to fly.<br/>
# f/ }* p( k9 U. t! Y: YWith this background, we can consider Maturana’s and Varela’s2 _+ ^- T8 ~2 n
definition of autopoiesis. A unity is characterized by describing the% w& u! |4 L' m) i6 |
organization that defines the unity as a member of a particular class( M9 \- a1 ^* ^3 G
that is, which can be seen to generate the observed behavior of unities
; D9 `6 K5 a2 U+ a; L% y1 b5 g5 [: fof that type. Maturana and Varela see living systems as being
) x5 q- [, q) O2 O+ r2 oessentially characterized as dynamic and autonomous and hold that it is
. |; F6 s* G# ?/ y' Htheir self-production which leads to these qualities. Thus the
" M& l8 t* h7 U" M+ `+ \' Corganization of living systems is one of self-production – autopoiesis.
/ O0 O2 ]7 |8 J. J+ PSuch an organization can, of course, be realized in infinitely many; B2 Q5 p$ Z) r* ^8 [! q w
structures.<br/>
# M3 U, `3 w+ h0 l; PA more explicit definition of an autopoietic system is<br/>2 F' N( E! U* S5 ^6 @6 Q ]
A dynamic system that is defined as a composite unity as a network of productions of components that,<br/>
7 [1 l( V- D$ L& l! |/ L3 Sa) through their interactions recursively regenerate the network of productions that produced them, and <br/>5 m2 e6 o8 m/ O
b) realize this network as a unity in the space in which they exist by
' F9 |; l, D& Q2 Qconstituting and specifying its boundaries as surfaces of cleavage from
6 v0 G6 }$ v) Z: [. rthe background through their preferential interactions within the
; c! D/ r. B$ q4 ^; e2 l% o) ]network, is an autopoietic system. Maturana (1980b, p. 29)<br/>
# [' S- F' w0 n1 J- Q: U, MThe first part of this quotation details the general idea of a system
5 o( e3 b2 g. Q3 R. O( ?3 `4 hof self-production, while the second specifies that the system must be
7 b5 W' |0 R! Wactually realized in an entity that produces its own boundaries. This
: }2 `# L7 D! q+ x. ]latter point, about producing boundaries, is particularly important
' z/ L; r2 j( ~when one attempts to apply autopoiesis to other domains, such as the
* E/ K' U9 E/ W! K( tsocial world, and is a recurring point of debate. Notice also that the
7 p9 X! z; t# N& V4 i$ Ndefinition does not specify that the realization must be a physical% t( H; q# N1 Q X$ Y
one, although in the case of a cell it clearly is. This leaves open the
, c# G I! Y1 g% u p8 aidea of some abstract autopoietic systems such as a set of concepts, a
7 i( n1 [9 {' X) \cellular automaton, or a process of communication. What might the
: t( D: w9 b5 F+ }& Mboundaries of such a system be? And would we really want to call such a" q" E" W8 m* \6 m( [( L5 G6 `
system “living”? Again, this is the subject of much debate – See
p" R& e+ S! M9 }5 A- I( Jsection 3.3.2<br/>
! |8 O& J( Q$ ~/ @0 L; m& |This somewhat bare concept is further developed by considering the
7 `( F- j- `) l$ }+ ^8 v+ @+ enature of such an organization. In particular, as an organization it
7 x1 i' R/ B8 swill involve particular relations among components. These relations, in
; c' G# ~- `% ^3 t) ?2 S: }the case of a physical system, must be of three types according to
- Y% m' H# x& AMaturana and Varela (1973): constitution, specification, and order.
8 A- j% M& R! o& i$ Q5 ERelations of constitution concern the physical topology of the system; } c% t) b3 O7 M; z& D
(say, a cell) – its three-dimensional geometry. For example, that it5 o' d4 O( }* V2 |) l8 g
has a cell membrane, that components are particular distances from each! f. x2 a, k5 q+ F- x: V8 l
other, that they are the required sizes and shapes. Relations of
t9 X9 H. C& x; _3 f! Fspecification determine that the components produced by the various
& X6 C' a' ?) q4 N, cproduction processes are in fact the specific ones necessary for the
8 x: f! W) F+ Wcontinuation of autopoiesis. Finally, relations of order concern the
% C4 `( P# ]% gdynamics of the processes – for example, that the appropriate amounts; y) M3 e! Y& O o- _& \" t! L
of various molecules are produced at the correct rate and at the7 D8 w7 E" C$ T1 Q1 D! |
correct time. Specific examples of these relations will be given later,5 K+ O( i7 `/ m$ V
but it can be seen that these correspond roughly to specifying the( X/ b: ?) D0 s; F: G$ ^7 }
“where”,”what”, and “when” of the complex production processes
1 k4 M- _- v2 p; I3 Y# V: `3 F( z4 Qoccurring in the cell.<br/>
8 x5 ?' v! P- c" q, ]; O$ hIt might appear that this description of relations “necessary” for
' o) h. X' N% u- ~0 T4 dautopoiesis has a functionalist, teleological tone. This is not really
8 @5 p$ j) i( E F) Z& `5 x* y( Xthe case, as Maturana and Varela strongly object to such explanations.4 p7 d# O. z" C" k
It is simply that, if such components and relationships do occur, they
5 l7 z) x8 S7 u: Z/ p& q3 X6 _" R* wgive rise to electrochemical processes that themselves produce further, B9 q- U B8 d( k
components and processes of the right types and at the right rates to0 C; v) d# |+ v( a1 _
generate an autopoietic system. But there is no necessity to this; it2 M. j3 m. t% v1 X
is simply a combination that does, or does not, occur, just as a plant; I) D3 W0 N0 ~( ?" r
may, or may not, grow depending on the combination of water, light, and
$ B' n1 @5 L& E, _) N! Anutrients.<br/>
; P u( d. t$ f- |5 D( O* tIn an early attempt to make this abstract characterization more7 Y' n3 \: `1 N) k1 M0 W
operational, a computer model of an autopoietic cellular automaton was
) b, |* m+ Q% D: Adeveloped together with a six-point key for identifying an autopoitic
( a9 w. Z2 ?6 D+ B- S8 S' Xsystem (Varela et al., 1974). The key is specified as follows:<br/>/ Y W; l4 y& ~$ f1 q- F
i) Determine, through interactions, if the unity has identifiable
0 \6 u M" z, ^& V+ b7 Hboundaries. If the boundaries can be determined, proceed to 2. If not,
+ t' c( b3 a9 n5 Cthe entity is indescribable and we can say nothing.<br/>4 ?: z3 b! C; B5 P. d
ii) Determine if ther are constitutive elements of the unity, that is,8 A7 \( d$ u7 q3 l2 C' j
components of the unity. If these components can be described, proceed7 p8 I/ `4 v, {
to 3. If not, the unity is an unanalyzable whole and therefore not an
; p* z: Q8 y1 @5 l( wautopoietic system.<br/>
. {# r9 J( w& X X0 Wiii) Determine if the unity is a mechanistic system, that is, the
3 M- Z% n7 M, d# d; t, Xcomponent properties are capable of satisfying certain relations that
0 `& I/ c/ |9 `( Y, wdetermine in the unity the interactions and transformations of these2 }' c Z _- h8 F3 Y
components. If this is the case, proceed to 4. If not, the unity is not
0 R- y: d1 L& G yan autopoietic system.<br/>: d8 E2 \; ^' ~4 P7 Z9 z2 p
iv) Determine if the components that constitute the boundaries of the9 G' e" }9 N# }2 ^) e8 y0 P6 v
unity constitute these boundaries through preferential neighborhood' j* W6 c- g" t ]- t
interactions and relations between themselves, as determined by their/ f( E$ g/ l3 Z9 ^
properties in the space of their interactions. If this is not the case,
, z! I" N; k6 C. d2 Jyou do not have an autopoietic unity because you are determining its# t0 y& E9 x% K& k) J
boundaries, not the unity itself. If 4 is the case, however, proceed to
# Z( o: N1 k5 O0 K5.<br/>: _# l/ m0 \" g2 }8 v: b$ _
v) Determine if the components of the boundaries of the unity are9 @1 |. J9 M( w* D* K" g' b& e
produced by the interactions of the components of the unity, either by: E9 b. z+ M& W- F0 R/ h
transformation of previously produced components, or by transformations9 B1 d Y- m7 ~) A6 V; G
and/or coupling of non-component elements that enter the unity trough
* w5 M# G6 p- I; F, K9 ^) Rits boundaries. If not, you do not have an autopoietic unity; if yes
6 B8 e, c! q3 Xproceed to 6.<br/>( G5 |1 {' C+ M/ Z2 c) v( s
vi) If all the other components of the unity are also produced by the4 t" a( ^. O. Y, J
interactions of its components as in 5, and if those which are not
6 s3 |; j! m3 e: Lproduced by the interactions of other components participate as
: F% }! v! E* M; V- F0 P4 Gnecessary permanent constitutive components in the production of other
0 U6 _6 m* e9 G0 [components, you have an autopoietic unity in the space in which its
# F/ o R* g) R! v8 C/ Ucomponents exist. If this is not the case, and there are components in; @7 z- e8 s3 _* C
the unity not produced by components of the unity as in 5, or if there+ B& O$ @3 {6 G2 q; E o
are components of the unity which do not participate in the production5 B! p! h; s0 D( ~: b a
of other components, you do not have an autopoietic unity.<br/>, p( j- k% C8 k C) o
The first three criteria are general, specifying that there is an/ ?; v0 Y, b* V- }& S" p# j$ Y
identifiable entity with a clear boundary, that it can be analyzed into
1 R7 S3 g3 V, U7 u, b; `0 ^- c1 q* \4 qcomponents, and that it operates mechanistically, i.e., its operation+ A/ F- F' v) ]* S% M' @* {
is determined by the properties and relations of its components. The6 L5 a5 ^1 I, I* r6 c0 i( X
core autopoietic ideas are specified in the last three points. These2 _4 u3 l5 W0 a* n6 e
describe a dynamic network of interacting processes of production (vi),
( A/ `0 V! c+ s% R, |) Kcontained within and producing a boundary (v) that is maintained by the8 X" J" I- D+ O+ m
preferential interactions of components. The key notions, especially" A% V& n1 K, o! x
when considering the extension of autopoiesis to nonphysical systems,
9 e- F; J @' H- Y+ n5 c1 ]are the idea of production of components, and the necessity for a0 q" @6 M# r4 h- E- e
boundary constituted by produced components.<br/># i0 {# O }1 `0 f; A5 x1 n* D
These key criteria will be applied to the cell in the next section.1 S; I& {" v/ {& U. L
This section will describe briefly embodiments of the autopoietic
( M+ E$ u1 I! J, l6 a2 erelations outlined above in the chemistry of the cell. Alberts et al.3 a! t: ~3 c& h( a4 R) I
or Freifelder are good introductions to molecular biology, as is Raven
0 i2 M% v: ^+ Fand Johnson to the cell.<br/>
& }+ j/ y, j! X( L# m( ]2.3 An illustration of Autopoiesis in the Cell<br/># r2 r2 v0 o# e$ [$ a
This section will describe briefly embodiments of the autopoietic
. _" T7 d, Y- Y' _+ orelations outlined above in the chemistry of the cell. Alberts et al.7 F' _% q- Y! \7 q# W2 u! ]# A. g
are good introductions to molecular biology, as is Raven and Johnson to
5 o& ?5 L* d; ?2 L, s: `& q& E! dthe cell.<br/>" a E! r- y; ]# \- G) n6 b$ L) W, d
2.3.1 Applying the Six Criteria<br/>
0 S1 @+ i& x1 J5 L6 zZeleny and Hufford analyze a typical cell with the six key points. A
6 Y; d2 d$ L$ G9 Sschematic of two typical cells is shown in Fig 2. One is a eukaryotic
# }; X) e v( Z. P, [! S" vcell, i.e., one that has a nucleus, and the other is a prokaryotic
0 u, H f# _( A1 u6 M! ~) _cell, which does not.<br/># q6 y$ y4 @8 N& h* q. P+ K
1. The cell has an identifiable boundary formed by the plasma membrane. Thus, the cell is identifiable.<br/>% N0 W9 \: b/ ~% x- \3 \
2.The cell has identifiable components such as the mitochondria, the
# F0 b+ d6 _* ]1 \! Anucleus, and the membranous network known as the endoplasmic reticulum.
k5 H$ j( G" L2 p( x* _Thus, the cell is analyzable.<br/>' o" b) x3 @0 h- W& e
3. The components have electrochemical properties that follow general4 P$ [. X$ ]( h0 S
physical laws determining the transformations and interactions that( Y1 w6 Q5 t# U* l8 y W. e4 S
occur within the cell. Thus, the cell is a mechanistic system.<br/>( u/ W6 ~) w$ i' C
4.The boundary of the cell is formed by a plasma membrane consisting of
& J; _& D# X+ X$ I+ tphospholipids molecules and certain proteins (fig 3). The lipid
+ I$ p1 i6 u/ W( z3 q8 s$ Qmolecules are aligned in a double layer, forming a selectively
5 l+ ?! Z, D, z, e7 n# o4 Jpermeable barrier; the proteins are wedged in this bilayer, mediating) v# m3 i7 G0 Q! F7 A" A
many of the membrane functions. A lipid molecule consists of two parts
" j* M6 ~$ ~, x, K8 O. _3 v+ p– a polar head, which is attracted to water, and a hydrocarbon (fatty)+ H8 C/ i* y) A Z
tail, which is repelled. In solution, the tails join together to form4 Z) `( H: X2 {0 S4 p& [
the two layers with the heads outside. The integral proteins also have/ y0 {! y" J& }" z: X! w
areas that seek or avoid water. The boundary is therefore, v( X! Y$ W3 ^
self-maintained through preferential neighborhood relations.<br/>
% |( c+ `1 J7 ^: p I0 n5. The lipid and protein components of the boundary are themselves; o3 |- U, w* [* P- ]! `% Q) S4 q
produced by the cell. For example, most of the lipid molecules required9 d, Z* G% J C6 N. I6 P
for new membrane formation are produced by the endoplasmic reticulum,
0 k( J t) B9 V/ l2 O. b, @! pwhich is itself a complex, membranous component of the cell. The
: o! [: I% E6 Zboundary components are thus self-produced.<br/>2 x! H+ L# ^2 p; F4 \( l, j1 f* v
6. All of the other components of the cell (e.g., the mitochondria, the( @+ ]; _6 s% c& K
nucleus, the ribosomes, the endoplasimic reticulum) are also produced# B+ b5 |0 w: |: B- m4 ?) B. l
by and within the cell. Certain chemicals (such as metal ions) not' @" _; G. e) N2 i% F- }2 R2 b. j
produced by the cell are imported through the membrane and then become" i$ W9 \! \, o% ]- _9 [. Y- o
part of the operations of the cell. Cell components are thus; H5 e# E& V$ J, J9 r
self-produced.<br/>" T9 w8 x' N1 a
2.3.2 Autopoietic Relations of Constitution, Specification, and Order<br/>
/ t# T8 ]$ j. c+ L5 BApart from the six-point key, autopoiesis was also defined by three
( Y2 u* V0 N# u2 v, A+ F! Znecessary types of relations. These can be illustrated as follows for a
* O4 z8 k( _. b' w9 j: ]3 ntypical cell.<br/>
! ~) C4 A/ w5 Q( I2.3.2.1 Relations of Constitution<br/>" e1 |; [& E7 L; u2 w
Relations of constitution determine the three-dimensional shape and
# ^& ~& R% J" |structure of the cell so as to enable the other relations of production
5 A9 A% a0 k. O# i- ]' cto be maintained. This occurs through the production of molecules9 N; i: U D& {, [7 A. z# s
which, through their particular stereochemical properties, enable other
% R2 ~6 g0 o, d( Z& Lprocesses to continue.<br/>
( D5 c1 l! P& ?* j! k# iAn obvious example is the construction of membranes or cell boundaries.4 U' n3 t T; ?3 {7 [' @4 ]' @
In animal cells, the membrane surrounding the mitochondria, like that
; n' L+ r. H; q) G, Qaround the cell itself, serves to harbor cell contents and control the
9 }, f0 {$ `* J; \1 A+ E8 Irate of reaction through diffusion. Various reactive molecules are: u* s- F, U5 t" |# b% _8 R
distributed along the inner membrane in an appropriate order to allow
! F( d. w5 l& V- y3 U* [& o7 Fenergy-producing sequences to proceed efficiently. In plant cells, in
: g g8 |9 ^4 M8 i/ ^" maddition to the plasma membrane, there is a cell wall, which consists* z' Q& {' ]% S5 Q. j
of cellulose, a material made up of long, straight chains of glucose! k9 d% @5 G j% {
units packed together to form strong rigid threads. These give plants
5 `% ^$ [) ?, n; Ntheir rigidity.<br/>
* J' L; M# m! d* c( bA second example is the active sites on enzymatic proteins. These act) c9 `+ l1 i6 r
as catalysts for most reactions, changing a particular substrate in an; X1 L8 |) a" v) i; Y" {8 `
appropriate way to allow it to react more easily. Generally, the active' T P6 J& q8 ~( p
site is found in certain specific parts of the enzyme molecule where: t2 t+ C7 ?; U5 l9 e# N6 Z
the configuration of amino acids is structured to fit the particular( n3 I$ f9 ^; ^0 i2 |. I
substrate, sometimes with the help of “activators” or co-enzymes. The6 p$ P( @% j/ S" O Y
substrate molecule interlocks with the active site and in so doing
9 s! n0 l& k1 z( cchanges appropriately so that it no longer fits, and thus frees itself.<br/>
/ D7 ~) p" }% {0 j r2.3.2.2 Relations of Specification<br/>
3 L+ r0 M% P. b$ BThese determine the identity, in chemical properties, of the components' a- e5 q$ H* y) s# q0 z0 ?
of the cell in such a way that through their interactions they# @$ r5 F0 M/ ]- q9 z
participate in the production of the cell. There are two main types of7 h5 u3 g }3 F" d2 Y/ @
structural correspondence, that among DNA, RNA, and the proteins they
* K6 k9 v/ x, b+ uproduce and that between enzymes and the substrates they catalyze.<br/>
4 n9 ~! g- @- pProtein synthesis is particularly complex because each protein is T# v- P6 d4 ?* h
formed by linking up to twenty different amino acids in a specific
5 T+ P$ e8 v+ Ycombination, often containing 300 or more units in all. This requires
: l. [: f# ?- i1 `$ g. x" ^8 {an RNA template molecule, tailor-made for each protein, containing6 q$ j R+ F7 ]( C2 l
specific spaces for each of the amino acids in order, together with an" M" B5 S+ b3 L" k7 s
enzyme and t-RNA for each acid.<br/>
N' [( b. }' s5 T2 EAs already mentioned, enzymes are necessary to help most of the
' y" {, z) e j' [reactions in the cell, and again, each specific reaction requires an6 }6 d5 G7 s: _$ r! y
enzyme specific to the reaction and to the substrate involved. Hundreds _% g5 Q9 r! Y7 |% q% K) x5 U
of such enzymes are needed, and all must be produced by the cell.<br/>
8 ?7 Z$ r" _3 h5 Q, Z. k( D2.3.2.3 Relations of Order<br/>! ~$ p3 m! E7 J* P5 H- ^. \
Relations of order concern the dynamics of the cell’s production# s4 v# i* z7 `# b3 K4 u: T# [) |
processes. Various chemicals and complex feedback loops ensure that
. z; y& E) ^) a, j' L, _both the rate and the sequence of the various production processes
7 o" k( X' D2 D. ^, w/ V: @continue autopoiesis. For instance, the production of energy through
9 N9 m1 D( D! _. foxidation is controlled by the amount of phosphate and ADP (adenosine
! S! O6 b) ?' H& G1 y9 e! k3 Mdiphosphate) in the mitochondria. At the same time, reactions that use
# z4 r7 B" A) T4 Z& ~ Venergy actually produce ADP and phosphate so that, automatically, a
) f6 m5 u: s# |' G) M/ h) ?high usage of energy leads to a high production rate of these necessary
! Y3 g7 ]: W& c x7 h) a8 Usubstances.<br/>
4 h: w2 }1 Z* y! T% K; [6 |+ r# ?2.3.3 Other Possible Autopoietic Systems<br/>
7 ]# i2 _6 F5 q2 a4 l/ DAn interesting question leading from the idea of the cell as an: P& c7 G3 @% _
autopoietic system is whether or not there are other instances of
2 M& c9 C8 [0 _( C& Fautopoietic systems. Are multicellular organisms also autopoietic; b' u; f1 x2 Y9 r7 N8 U
systems? Maturana is equivocal, suggesting that organisms such as
* n0 _$ j+ q, Manimals and plants may be second-order autopoietic systems, with the( }' k/ f7 j' W7 z6 D
components being not the cells themselves but various molecules
7 q% {* n5 F) Qproduced by the cells. On the other hand, he suggests that some
1 I8 g- x# B: L% Tcellular systems may not actually constitute autopoietic systems, but
2 [6 m5 `& R: M" H5 ~3 ~0 w' qmay be merely colonies. What about a system that appears to have a
: Y# X7 J$ \$ y+ ^closed and circular organization but is not generally classified as, B7 }, e L5 ?2 V1 J
living, such as the pilot light of a gas boiler? Finally, what about
* j! y: z% h! xnonphysical systems such as the autopoietic automata mentioned in- c C& P7 b; [+ ?! K6 {0 d
section 2.2.1 and described more fully in section 4.4, or systems such, c" _/ P" d7 o% G
as a set of ideas or a society? These possibilities will be discussed0 T; n, U0 D# h7 ` r
in more detail in Section 3.3.<br/>$ h/ t! e8 O( V
2.4.Applications of Autopoiesis in Biology and Chemistry<br/>5 u2 K* w- e8 g
One would have expected that, given the importance and nature of its% p3 G9 O5 O/ [' m5 z8 R# _
claims, autopoiesis would have had a major impact on the field of. q1 _; d, f, P) G) r+ Y
biology. In fact, for many years there was a noticeable reluctance to/ r; G1 l" {* Y5 a3 q/ @
take the ideas seriously at all. In 1979, I wrote to an eminent British
" A Z1 s1 F/ a% P2 Ybiologist – Professor Steven Rose at the Open University – querying the7 }: E M! ^" O; g
status of autopoiesis. He replied to the effect that he did not wish to
! z, q" ~9 A' T: l" N9 B/ T' mcomment on autopoiesis but that Maturana was a reputable biologist. One
/ r, G* a6 z$ ~, A) W5 j6 A& s8 C3 nnotable exception is Lynn Margulis, whose own theory, that eukaryotic
; `/ j7 e" V9 C+ O" Z" Bcells evolved through the symbiosis of simpler units, is itself quite' d! z$ b( N8 ^) @- T- k
controversial.<br/>. u; p! |$ q- V" `7 B2 C/ D# r# I
However, recently interest has been growing in two areas: research into" W+ f0 v: S$ H" L1 D# _9 i
the origins of life and the creation of chemical systems that, although- p3 l" F1 S- I: d( R6 Y
not living, display some of the characteristics of autopoietic6 Z& O3 c7 C, e- T- ?. a8 F$ D2 e
self-production. Autopoiesis has also been compared with Prigogine’s v3 I4 B @1 g9 Z* s$ w
dissipative structures. Varela has also pursued work on the nature of
5 P* h, J6 F( E5 k4 ?the immune system, viewing it as organizationally closed but not# ~ ?" a: V+ @/ L( |; v
autopoietic. However, as this topic is very technical and not of
; e) f5 q, K' |0 Y5 h: j$ sprimary relevance, it cannot be pursued here.<br/>
: p" b7 f9 S" L, D- A( G0 o2.4.1 Minimal Cells and the Origin of Life<br/>
`3 c. d' _) A7 u2 U+ l# `7 p) xThere are two main lines of approach to theories concerning the origin8 {% W+ b. ~' |! \* P E
of life on Earth. In the first approach, based on study of the enzymes/ J3 P0 x9 a9 \) P8 p% A- E
and genes, life is characterized as being molecular and a defining
" C3 F q$ }5 R4 {1 D* ^/ `! ^" g2 D" pfeature is the structure and function of the genes. In the second
3 j6 G" e/ o1 {# d# x+ P0 Zapproach, life is characterized as cellular, and its defining feature
. g* X$ b( E3 L& f( @* j2 H: Kis metabolic functioning within the cell. However, neither approach can6 `* ~. a; G0 M$ J8 K* s7 F
really specify a standard or model for life against which important5 z6 b: H* f" K* F
questions may be answered. In particular, at what point did prebiotic) h- W9 x* M& Z
chemical systems become biotic living systems? And how could we% G; u9 M7 @/ s; S( v1 E8 R' `
recognize nonterrestrial living systems. Which might be radically- h/ H/ g* f. L
different in structure from our own?<br/>
% R, R: Y3 c/ `7 g" IFleischaker proposes that the concept of autopoiesis, together with
& D! K2 g6 A+ \% Cnotions of minimal cell, can provide a sound theoretical framework to' b8 K' R8 }$ h
tackle these questions within the second tradition mentioned above.8 j E; K! d5 t0 K* T7 v8 b
Autopoiesis clearly does aim to provide a specific and operationally
+ o6 s# E, |, ]1 V% ?; e( Ruseful definition of life, although Fleischaker argues that the concept
: X' [. p* }$ Z. J# r- Hof autopoiesis does need some modification. This modification would
" F' _) K. [( n$ d" R' B/ }+ C. grestrict “living” systems to autopoietic system in the physical domain
& n W# W% A- x+ qrather that allow the possibility of nonphysical living systems, a
" Y% ^2 g3 c" Y" k& Npossibility which ( as mentioned above) is left open by the formal
( @4 L+ J+ ]( idefinition of autopoiesis. This will be discussed in Section 3.3.2<br/>, V4 w, c" ^# n( i J
Given autopoiesis (or modified version) as a definition of life, the
3 _; N" y7 k [: A% h2 h2 D& mnext step in theorizing about the origin of life is to consider how an6 h9 p4 `6 D( `& a p
elementary autopoietic system might have formed. Note that autopoiesis
: ?9 R; z) F0 z$ xis all or nothing. A self-producing system either exists and produces2 z/ r7 d0 ~: ?
itself or it does not – there can be no halfway stage. This leads to
% n w8 E$ N* q% jthe idea of a theoretical “minimal” cell which could plausibly emerge,3 O% j) q* I! j# _5 ?
given the early conditions on earth. In fact, Fleischaker considers
+ v8 [8 f) q, T8 ^three different characterizations of minimal cells: a minimal cell
- x. `. p y" \representative of the evolved life forms that we know today; a minimal
0 L* Y( z* B' w" h: i; Wcell that would characterize both terrestrial and nonterrestrial life
8 B& S! W, J# h( Kregardless of its constituents.<br/>
# F. i2 @$ o$ ^, MAbout the last, little can be put forward beyond the six-point
% {2 [, e: V. ]5 X5 X8 \autopoietic characteristics in the physical space; to be more specific
; R9 e( }% [/ `1 m# t! U) ~would constrain the possibilities unnecessarily. On the other hand, we: z5 n# Y& m( W, u$ O' W* G3 g( n7 V
can be quite specific about a modern-day cell. Such a cell could be* F9 \+ l: G. A7 Y' u9 X/ d
described as “a volume of cytoplasmic solvent capable of DNA-cycled,0 I! ^* T: S, D% F
ATP-driven and enzyme-mediated metabolism enclosed within a
$ f/ ?$ H8 E$ j6 Q+ j& ]' wphosphor-lipoprotein membrane capable of energy transduction”, This! I: F! t0 ~) y
generalized specification can cover both prokaryotes (bacterial) and
% T( v, N" t- w2 ]7 u; Leukaryotes (algal, fungal, animal, and plant cells) even though there- s8 e, V- [1 z: r% B& Y
are important differences in their operation.<br/>
$ {4 O2 Y! u% b$ i. O5 `. NThe most interesting minimal cell scenario concerns the origin of life.& N( A; F" R/ m/ a$ H8 y5 m
The first cell need be only a very basic cell without the later
. j3 L9 K2 h- z* s; z- O7 eelaborations such as enzymes. Fleischaker suggests that such a cell( M S5 T2 ?: y) C" A
must exhibit a number of operations (Fig.2.4):<br/> ?& ?: [7 ?/ }: l
1、The cell must demonstrate the formation and maintenance of a boundary
* R2 ]! _3 A0 G' Sstructure that creates a hospitable inner environment and allows
4 S9 S d: _2 G9 p0 dselective permeability for incoming and outgoing molecules and ions.. M0 G; ? q- ~
The lipid bilayer found in contemporary cells is a good possibility
& e. ?% c) W3 p9 D; E6 l, G b# hsince the hydropholic nature of lipid molecules leads them to form
6 J' u: [4 {7 V: _ p* Qclosed spheres in order to avoid contact with water. Lipid bilayers are
2 E1 R: w. [% |& s9 N4 c4 `- @also permeable in certain ways – for example, to flows of protons or
L& ^: T8 I" q6 \1 T8 Xsodium atoms – without the need for the complex enzymes prevalent in
8 F: r" v+ D/ R/ zcontemporary cells.<br/>( Y# \/ L( O- S9 P
2. The cell must also demonstrate some form of active energy4 K( |- H" f7 H& w/ z- r+ `
transduction to maintain it away from entropic chemical equilibrium.
* D: o4 f: w: X2 v s& R) yOne possibility is an early form of photopigment system driven by) B: P" l5 ` _5 O# Q
light. Pigment molecules would become embedded in the membrane and act ]8 I+ }. u4 T% \* l/ Z; \
as proton pumps, leading to the concentration of variety of raw3 M% y6 P5 `/ F' S) j7 w
material in the cell.<br/>
! J% b9 |/ O+ ]+ L* f# X; Z3. The cell would also need to transport and transform material+ o! \$ w3 z+ h; H U7 A8 D
elements and use these in the production of the cell’s components and
- F/ ^' q( w# k( Hits boundary. A possible start in this direction would be the import of
$ ?. B2 ~5 N' _. `: Gcarbon dioxide and the physio-chemical transformation of its carbon and
" ?, U" F8 u8 }# Y# Zoxygen through light-driven carbon fixation.<br/>
% {# y P( U+ nWhat is important is not the particular mechanisms for any of these
/ h7 E$ L! `5 s% [7 I' @9 Ygeneral operations but that whichever mechanisms are postulated, all5 R& ]0 w. J& d0 M+ B
operations need to be part of a continuous network to form a dynamic,! E$ R- u, L! x6 L6 |" d% I
self-producing whole.<br/>" H; d1 A' Y- O2 J
2.4.2 Chemical Autopoiesis<br/>
9 g1 }, Y4 q# ` y) ?Beyond theoretical constructs of minimal cells, it is also interesting
+ x! f8 P1 F( T2 yto look at attempts to identify or create chemical systems based on5 c/ I4 O5 ~! T) E9 c
autopoietic criteria, and to consider whether or not these are living.0 e( P" t: ?2 N! t) R3 W3 p
We shall look at three examples: autocatalytic processes, osmotic
; f$ | J4 s% L% V3 R. n5 B% Ggrowth, and self-replicating micelles.<br/>
) f5 I6 B x# g2.4.2.1. Autocatalytic Reactions<br/>
$ f/ x5 U, E2 U8 WA catalyst is a molecular substance whose presence is necessary for the& r" c" E4 q: _
occurrence of a particular chemical reaction, or which speeds the
% K# ]# }8 w( p" g8 f! n9 ` x, z# \reaction up, but which is not changed by the reaction. The complex7 }( N/ q. w% ^/ C; l. T
productions of contemporary cells (as opposed to cells that may have Q* N7 ~4 z! K- r: U
existed at the origin of life) require many catalysts, and this is one
9 ^+ h8 b& T, ?9 F; oof the main functions of the enzymes. An autocatalytic process is one
$ G3 s2 P/ h3 ^8 @# vin which the specific catalysts required are themselves produced as
0 p$ y, |4 G" G% A* mby-products of the reactions. The process thus self-catalyzes. An% u9 ?+ ]/ R" l5 e, S
example is RNA itself which, in certain circumstances, can form a/ S. u; f+ c, e* [! T% `
complex surface that acts like an enzyme in reaction with other RNA
% v! N) D9 F3 V9 E" _molecules (Alberts et al.) Kauffman has a detailed discussion within
1 v" R7 x5 C z0 v' G; Z- Z+ U' d5 fthe context of complexity theory.<br/>
3 n, }- A9 b7 f6 V* GAlthough this process can be described as a self-referring interaction,+ j% X, x( z/ g' {
the system does not qualify as autopoietic because it does not produce4 c; c2 o6 _: j: n5 w
its own boundary components and thus cannot establish itself as an; z( C9 I; [+ @2 A, i! R( p
autonomous operational entity (Maturana and Varela). Complex," K O& r& F7 ]7 [
interdependent chemical processes abound in nature, but they are not8 z/ D" Y# s2 M% H( b P1 Z
autopoietic unless they form self-bounded unities that embody the
7 p, ]; P! D$ c8 P. Q5 Pautopoietic organization.<br/>
; _* ]# k- J/ N$ z4 h2.4.2.2 Osmotic Growth<br/>
$ ]) w& a2 z4 ^Zeleny and Hufford have suggested that a particular form of osmotic4 a4 m5 Z* |9 C
growth, studied by Leduc, can be seen as autopoietic. The growth is) v" `0 C' e7 _& a W" @
precipitation of inorganic salt that expands and forms a permeable: v0 {- E8 Y: S3 v4 a% ]6 T! w; _
osmotic boundary. This can be demonstrated by putting calcium chloride4 M8 z( ?! S; o$ a' d
into a saturated solution of sodium phosphate. Interaction of the' X5 P' |9 P1 l+ `# B4 w
calcium and phosphate ions leads to the precipitation of calcium
1 r- E0 g3 ~" B7 P" m% d; Gphosphate in a thin boundary layer. This layer then separates the
1 S# C3 {. d2 N' Dphosphate from the calcium, water enters through the boundary by
9 V8 B* G* ]6 I7 U5 I( F6 o1 Wosmosis, and the increased internal pressure breaks the precipitated T0 y- Y- b7 U# P
calcium phosphate. This break allows further contact between the/ ?0 Q2 ~1 u) G* \) t3 h4 ]1 A
internal calcium and the external phosphate, leading to further
& s5 G, j. R0 }" m* ]8 Y$ e: Q) uprecipitation. Thus the precipitated layer grows.<br/>
9 h: x$ B+ W1 p5 {; D @- r) v& [Zeleny and Hufford argue that this system fulfills the six autopoietic criteria:<br/>
4 Y( U& x$ @6 k8 _& N1. It is distinguishable entity because of its precipitate boundary.<br/>
* c2 O; D9 |6 p6 b2. It is analyzable into components such as the calcium phosphate boundary and the calcium chloride.<br/>
3 P4 v( `3 y/ @# K2 ~; O! g3. It follows mechanistic laws.<br/>
! f" I+ [2 H4 O3 H! a$ ^7 X4. The boundary components (calcium phosphate) aggregate because of their preferred neighborhood relations.<br/>8 G: A5 D0 c; m" P& B O ?
5. The boundary components are formed by the interaction of internal% e% J9 H& o B. Y
and external components following osmosis through the membrane.<br/>/ }0 ?3 G7 k& k
6. The components (calcium chloride) are not produced by the cell but* d( D" T# q: ?" ^
are permanent constituent components in the production of other& W/ n) k5 W. `: @
components (the precipitate)<br/>
" Q; {/ O- m+ h/ lThis hypothesis does cause problems, as Leduc’s system is clearly
) k2 ^- f8 Y. @2 o% P% V3 }inorganic and not what would be called living. If it is accepted that8 z5 V$ j; S0 ]8 |6 [* u
the system does properly fulfill the criteria of autopoiesis, i.e.,) X; d) O3 U2 ^. y N5 f/ O
that it is an autopoietic system as currently defined, then either we- s' Z1 B% T U; G0 G1 B( G
must expand our concept of living or accept that autopoiesis is in need
3 B, c: H( b3 ]. xof redefinition to exclude such examples. In fact, it is debatable2 U! i* d' R+ K" Q2 u# ~
whether or not this osmotic growth does correctly fulfill the six( c) z3 {; W9 ?0 F4 o1 s
criteria. It certainly meets the first three, but it is not clear that
3 ?/ d6 ~8 P4 q6 u4 Xit is a dynamic network of processes of production.<br/>" J' U& m" ^' a/ f( q8 q3 P
As for the fourth criterion, the precipitate that forms the boundary is, D/ y; r1 A |* z" Z3 M
unlike a cell membrane. It is static and inactive, more like a stone# H( K( I3 s5 X* A, p- v! O( }/ E+ t4 ~2 t
wall than an active membrane. It is not formed through “preferential
, ~8 ?' U5 D: h! Wneighborhood interactions”; in fact, once formed, it does not interact
5 C3 X0 D# |0 U( f" N& u8 c) @at all. Considering the fifth criterion, the boundary components are7 m! F$ }1 x, n6 [: |+ r7 G
not continuously produced by the internal processes of production.
9 ^7 Z5 m! m* d4 uRather, a split or rupture occurs and more boundary is precipitated at! x4 s4 I6 P- u7 X9 P
the split through the interaction of internal and external chemicals.
/ ^( @2 V9 X8 ?, o, h( HIt is only because of, and at, the rupture that new boundary is& Z' u% r' H; |- G& i
produced. Finally, chloride, which is introduced artificially at the
2 D7 f7 T* D4 Q# gbeginning, is not produced by the system, and eventually runs out.<br/>% H) u/ |8 D# s. R' H
2.4.2.3 Self-replicating Micelles<br/>
- b5 |% ]6 f( s h+ [ p; g* Z7 ?An approach with more potential, currently being researched by Bachmann* l& W+ U$ e# U$ x# y6 W
and colleagues, was first proposed by Luisi. It has been discussed by
- H; [* ?+ G: }$ ^* c% Z7 j# s5 gMaddox and Hadlington. A micelle is a small droplet of an organic5 b0 ?# ?3 S2 c4 y
chemical such as alcohol stabilized in an aqueous solution by a
) W3 O, X0 W! t* ?# f, |3 k) B' mboundary or “surfactant” A reverse micelle is a droplet of water
' m z" P; l( c: C, b- W- qsimilarly stabilized in an organic solvent. Chemical reactions occur7 D' N' k9 c! t
within the micelle, producing more of the boundary surfactant.- _6 C& |! ~! g7 D/ f- E5 o; P
Eventually, this leads to the splitting of the micelle and the
8 S: d; ?. O) H7 }0 Y- L4 L! ]9 Y. zgeneration of a new one, a process of self-replication. Experiments" w A5 [" ]/ a$ |2 b
have been carried out with both ordinary and reverse micelles and with
* p/ Q! J, u& F7 H; ean enzymatically driven system.<br/>7 F; W' H! ]: j( l6 l$ ^- b
In the reverse micelle experiments, the water droplets contain' O( x% Z# B0 I. E5 R
dissolved lithium hydroxide, one of the surfactants is sodium
& R: Z) N* R2 O4 ^8 K) U! Yoctanoate, and the other is 1-octanol, which is also a solvent. The2 q. V5 p. A( H; j1 |. `
other solvent is isooctane. The main reaction is one in which the* ^- I1 b: _% O0 e% z& m+ S
components of the boundary are themselves produced at the boundary.: ^2 e7 S4 ^) J
Octyl octanoate is hydrolyzed using the lithium as a catalyst. This% W8 v- l5 }$ q T4 L! H) l
produces both the surfactants (sodium octanoate and 1-octanol). Since
' r. M7 m- ] W$ Sthe lithium hydroxide is insoluble in the organic solvent, it remains
- y) O) y% Y) cwithin the water micelle, thus confining the reaction to the boundary2 u# M$ Y8 D; ~) q p% p! q
layer. Once the system is initiated, large numbers of new micelles are3 }! ?2 z, M m, Z5 q3 c
produced, although the average size of the micelles decreases.<br/>
0 h* ?5 s, l% F) |* J/ q' ^It is not clear that these systems could yet be called autopoietic./ L$ G1 T4 }# |/ I
First, the raw materials(the water-lithium mixture or the enzyme- v4 l+ J7 s M y1 Z
catalyst) are not produced within the system. This limits the amount of. V4 m& p$ X2 X5 p. ^, p" {+ i
replication which can occur; the system eventually stops. Even if these3 i6 w0 i5 V4 o/ x3 b0 A( z
materials could be added on a regular basis, the system would still not
% ]( g3 [1 x0 [* X0 gbe self-producing. Second, the single-layer surfactant does not allow2 j: M @+ ^4 c# G* }+ p) K: p
transport of raw materials into the micelle. For this to happen, a
! L( g; U0 c" p* o9 ^2 x3 Ldouble-layer boundary would be necessary, as exists in actual cell
6 p3 s& k) E) Q3 p. O& s( Xmembranes. Moreover, the researchers themselves, and seem most
* W% z5 I, ^2 ]5 U" Qinterested in the fact that the micelles reproduce themselves, and seem1 W }9 J' R# h/ J" ` A
to identify this as autopoietic. However, reproduction of the whole is% T! p- Y0 m B% N. p6 B
quite secondary to the autopoietic process of self-production of
3 M9 O3 Y8 N9 O& [' W7 L" rcomponents. Nevertheless, this does represent an interesting step) G% r- p: w* F3 b2 E) h
toward generating real autopoietic systems. |
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