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Bathybius Haeckelii and the psychology of scientific discovery
NICOLAAS
BATHYBIUS
A. RUPKE
HAECKELII
PSYCHOLOGY
AND
THE
OF SCIENTIFIC
DISCOVERY THEORY INSTEAD CONTROLLED THE ‘DISCOVERY’ FORM
OF OBSERVED DATA LATE 19th CENTURY OF A PRIMITIVE OF LIFE
THE TRADITIONAL image of the scientist as an objective fact finder has become seriously tarnished by recent work in the history and philosophy of science. ’ It is argued that the growth of science is not always brought about by a reasoned debate based on objective evidence. Instead, scientific discovery seems to be controlled quite as much by certain psychological factors such as respect for a theoretical superstructure. The debate around T. S. Kuhn’s The Structure of Scientific Revolutions has brought similar iconoclastic aspects of scientific conduct to the attention of a cross section of the scholarly community.’ Without wanting to enter into the controversy generated by Kuhn’s book,3 this paper records one of the better examples from the annals of science to show how respect for a theoretical superstructure brought about a fictitious the heuristic value century produced called Bathybius,
discovery. Specifically, it records how confidence in of evolutionary theory in the second half of the 19th the discovery of a fictitious primitive form of life, its sub-division into two genera, its reported occur-
rence over vast regions of the ocean floor, its identification in the geologic record, and its wide acceptance in the life and earth sciences for the period of almost a decade. Background Shortly
after the publication
to the ‘Discovery’
of Darwin’s
The Ongin
of Species
(1859),
1 See review paper by S. G. Brush, Science 183, 1164 (1974). 2T. S. Kuhn, The Structure of Scientific Reuolutions Univ. of Chicago Press, Chicago, 2nd edn., 1970. 3See for example Ctiticism nnd the Growth of Knowledge, I. Lakatos and A. Musgrave (eds.) Cambridge Univ. Press, Cambridge, 1970. Stud. Hist. Phil. Sci 7.( 1976), No. 1. Printed in Great Britain 53
54
Studies
the conceptual
in History
need was felt by a number
and Philosophy
of Darwin’s
of Science
supporters
to
link the late 18th century nebular hypothesis of planetary evolution with the hypothesis of organic evolution and establish by that the philosophy of ‘universal transformism’. The link was thought to consist of factual evidence for the origin of life out of inorganic matter, i.e. a&genesis.
Howeyer,
at about
the same time,
Pasteur
conducted
his
classic experiments on fermentation (1860-1866) and made a cogent case for the germ theory of fermentation and against abiogenesis. In the midst of the controversy generated by Pasteur’s experiments, the German zoologist E. H. Haeckel reported in his Generelle Morphologie der Organismen (1866) on the existence of a group of very primitive microbes, which he called Monera.’ A Moneron was defined as a primitive form of life consisting of undifferentiated protoplasm and lacking a nucleus. In a separate monograph on this group, Haeckel described in some detail a number of different Moneru, among which the most primitive of all which he called Protamoeba primitiu6 It was described as being entirely homogeneous and reproducing itself by process of binary fission (Figure 1). The primitive level of organization of the Monera was interpreted to indicate that the group represented life in statu nascendi, and as such it made abiogenesis conceivable.
Figure 1 Protamoeba
primitiva
(Haeckel), O-04 mm in dia (From reference 13).
The ‘Discovery’
of Bathybius
At about the same time that Haeckel announced the existence of the Moneru, the English zoologist T. H. Huxley examined a number (he did not mention how many) of mud samples dredged during an 1857 4L Pasteur, Ann Sci nut. Part. Zoo1 16, 5 (1861). SE. H. Haeckel, Generelle Mosphologie de7 Organismen 6E. H. Haeckel, Jenu Z Med Naturw. 4,64 (1868).
(Berlin, 1866) p. 135.
Bathybius Haeckeliiand
expedition
the Psychology of Scientific Discovery
aboard the ‘Cyclops’
northwest
55
of Ireland.
The mud samples
had been preserved in alcohol. Huxley, employing a special microscope with ‘a magnifying power of 1200 diameters’, 7 observed in the ooze a gelatinous protoplasm
substance with a granular texture. in a primitive state of organization
of Haeckel’s
Moneru.
In a paper
depths in the North Atlantic ‘I conceive they
are
that
the granule-heaps
imbedded
represent
the Radiolaria,
characterise
Ocean’
form
described
of those
by Haeckel
this new “Moner” Professor
simple
organisms
of protoplasm.
“Urschleim”,
animated
in his “Monographie name
in the University
beings
gelatinous Take
away
would
matter
in which
the cysts
very nearly
which
resemble
which must,
I think, be regarded
which
recently
have
der Moneren”.
of Bathybius, of Jena,
living at great
he wrote:
and a dead Sphaeroroum
the generic
of Zoology
(1868)
and the transparent
masses
one of the masses of this deep-sea a new
‘On some
He interpreted this as and identified it as one
I propose
been
to confer
and to call it after
B. Hueckelii
as
so well upon
the eminent
‘7
Inside the gelatinous substance Huxley identified two types of coccoliths which he called Cyatholithi and Discolithi. These he interpreted to be skeletal components of Bathybius Haeckelii, like spicules in sponges (Fig. 2).
Figure 2 Bathybius Haeckelii (Huxley),
O-1 mm in dia (From
reference
10).
Studies
56
The
existence
Thompson ‘Challenger’ Atlantic
of Bathybius
who later expedition.
Ocean
floor
in History and Philosophy
was confirmed
of Science
by Sir Charles
Wyville
was to become the chief scientist to the Thompson examined an ooze sample from the
and he remarked
in a paper ‘On the depths of the
sea’ (1869): ‘This
mud was actially
egg mixed sarcode.
alive; it stuck
with it; and the glairy
Prof.
Huxley
regards
together
in lumps,
mass proved,
this as a distinct
as if there
were white
under the microscope, creature,
of
to be a living
and calls it Bathybius.
”
In more detail Wyville Thompson described Bathybius in his classic of oceanography The Depths of the Sea ( 1873).9 In his ‘BeitrZge zur Plastidentheorie’ (1870), Haeckel exaggerated Huxley’s report by interpreting it to mean ‘that the sea floor of the open ocean at greater depths (below 5000 ft) is covered with enormous masses of free living protoplasm’.” He enthusiastically remarked that the discovery of Bathybius had turned the ‘Urschleim’ of the German ‘Naturphilosophie’ into a complete truth. Haeckel had himself obtained one sample of deep-sea mud, dredged by Wyville Thompson and W. B. Carpenter off the south-west coast of Ireland. The sample had been sent to him preserved in alcohol. Haeckel also observed the gelatinous substance with its granular texture which he coloured with a carmine solution and interpreted as real protoplasm. He thought it likely, though not entirely certain, that the coccoliths were skeletal components of Bathybius. Huxley accepted Haeckel’s exaggeration of his 1868 report and he added to this an exaggerated account of Haeckel’s description of Bathybius in a speech before the Royal Geographical Society in 1870. He said with respect to his by now reputed discovery: ‘Evidence Atlantic, forms This
of its existence and wherever
one continuous opinion
had published
has been
had been found the Indian
scum
of living matter
confirmed
an admirable
Ocean
account
throughout had been
the whole surveyed,
North
girding the whole surface
in all its essential of specimens
details
obtained
and South
so that it probably
by Prof.
of the earth. Haeckel,
who
by him.’ l1
The existence of masses of free protoplasm or ‘Urschleim’ on the sea floor was even more suggestive of a form of life in statu nascendi than Protamoeba primitiva. In a speech on ‘Das Leben in den griissten Meerestiefen’ (1870) Haeckel expressed the belief that it ‘was virtually certain that Bathybius originated by process of abiogenesis. More in general he argued that the question of the origin of life could not be 7T. H. Huxley, Quart. J. Microsc. London 8, 203 (1868). *c. W. Thompson, Ann Mug. nut. Hist. 4, 112 (1869). gC. W. Thompson, The Depths of the Sea (London, 1873) p. 410. 10~. H. Haeckel, Jena. Z Med Naturw. 5, 492 (1870). 11~. H. Huxley, Proc. R geogrl. Sot. 15, 37 (1871).
Bathybius
Haeckeliiand
solved
by
through
the Psychology
experiment
(an
a philosophical
The discovery
of Scientific
apparent
57
Discovery
reference
to Pasteur),
but
only
approach. l2
of Bathybius
and of the other Monera
established
the
link between planetary evolution and organic evolution. In his widely read Natiirliche Sch6pf&zgsgeschichte (1870) Haeckel explicitly wrote: ‘Whenever result
previously
of the organic
at the time.
This main problem
the extremely that
are
one tried
important
not
and that
abiogenesis
has gained
between originates
Kant’s known
such
only since we have understood of
organs,
feed,
a degree
that
consist
and reproduce.
and Lamarck’s
is the marvellous
a single
of evolution. Bathybius
chemical
the hypothesis
as to entitle
one type exists which still today This
theory
of just
cosmogeny
to know
them as organisms
As a result,
of probability
faiied as a
that one knew
has been solved only since we have become
up till now,
by abiogenesis.
and described
up
still grow,
one immediately
abiogenesis,
of even the most simple organisms
Monera,
at all made
compound,
Monera
to visualize
composition
of
it to fill the gap
Already
probably Haeckelii,
among
the
continuously discovered
by Huxley.‘13
The Bathybius
bandwagon
The discovery of Bathybius Haeckelii generated a great deal of excitement in the life and earth sciences and a number of biologists and geologists continued the investigation of this Moneron. The German biologist 0. Schmidt reported in a paper ‘uber Coccolithen and Rhabdolithen’ (1870) that in the course of an oceanoLgraphic expedition in the Adriatic Sea he had found evidence of the existence of Bathybius there as well. In addition, he reported that he had observed Bathybius in ooze samples that had no alcohol added to them (‘Der frisch aus dem Meere gehobene Bathybius zeigt . . . genau jene Erscheinungen, welche die in Weingeist conservirten Proben wahrnehmen lassen.‘) l4 In addition to the coccoliths, he observed more rod-shaped particles which he called rhabdoliths. He however did not believe that they were part of Bathybius. In the same year, the German geologist C. W. von Gtimbel published the results of his study of a number of deep-sea mud samples, also In his preserved in alcohol. ‘Vorlaufige Mitteilungen iiber Tiefseeschlamm’ ( 1870) h e concluded, in support of the work by Huxley and Haeckel, that Bathybius with its coccoliths formed a living substance. In addition, he reported that its occurrence was not confined to the bathyal environment, but that it existed also in shallower marine environments and all around the world (‘. . . dass Coccolithen ’ 2E. I% Haeckel, Snmmlung Gemeinversth’ndlicher Wissenschaftlicher Vortriige, Heft 140, 1 (1870). t3E. H. Haeckel, Natiirliche SchGpfutagsgeschichte (Berlin, 1870), p. 306. Quote translated from the German. t40. Schmidt, Sitzungsber. Kaberl. Akad Wiss. Wien Math Natunu. K. 62. 669 (1870).
58
Studies
and Philosophy
of Science
in allen Meeren und in allen Meerestiefen vorkommen’).” of the fact that coccoliths occur in many limestones as had
(Bathybius) On account been
in History
established
emphasized
by
the
English
the lithogenetic
geologist
importance
H. C.
Sorby,
of Bathybius
Giimbel
in the geologic
record. Earlier on, immediately after Huxley’s discovery, Bathybius had been identified in the geologic record by the English geologist W. B. Carpenter. At that time a controversy existed with respect to an inorganic banded structure of ophicalcites in Precambrian rocks in Canada. The Canadian geologist J. W. Dawson interpreted these structures as organic, produced by a gigantic foraminifer, which he called
Eozoiin
In support
Canadense.
of Dawson’s
organic
interpret-
ation, Carpenter cited the discovery of Bathybius thinking it likely that it had existed through all of geologic time and that, if it had developed a shell, it would have resembled Eozoiin Canadense. (‘. . . if Bathybius, like the testaceous Rhizopods, could form for itself a shelly envelope, that envelope would closely resemble Eozoijn. Further, as Prof. Huxley has proved the existence of Bathybius through a great range, not merely of depth but of temperature, I cannot but think it probable that it has existed continuously in the deep seas of all geological epochs.‘)“j A still lower Moner than Bathybius was discovered in 1874 along the coast of Grinnell Land by the U.S. Arctic expedition aboard the ‘Polaris’. The discovery was made by the German E. Bessels, surgeon and naturalist to the expedition. It was characterized by the absence of coccoliths, and its movements were described as amoeboid. Bessels called it Protobathybius Robesonii and he reported his discovery in Nature (1874). A description of it was also included in A. S. Packard’s Life Histories of Animals (1876) (Figure 3): ‘It is mainly
distinguished
and the Cyatholithes. whence
the
intensily
name
drops,
given
by a solution
considerable soluble
particles
refracting in ether.
of carmine
from
Bathybius
For this reason
to it. It consists of carmine power,
foreign
of nearly
in ammonia.
and besides
It manifests
or other
by the absence
of both
I take it to be an older form
very
marked
substances
pure protoplasm,
It contains
the latter
the Discolithes than Bathybius,
a great
amoeboid suspended
tinged
most
fine gray granules
of
number
of oleaginous
motions
and takes up
in the water in which it
is kept.“’
This paper is not intended as a bibliography of Bathybius Haeckelii. Suffice therefore to mention that the discovery was reported in such influential publications as the Archives des Sciences Physiques et i ‘C. W. van Giimbel, N. Jb. Miner. Geol. Palaeont. 753 (1870). 16~. B. Carpenter, Proc. R. Sot. London 17 191 (1868). 1 ‘A. S. Packard, Life Histories of Animals (New York, 1876) p. 3.
Bathybius
Haeckelii
and the Psychology
Figure 3 Protobathybius
ZVutureZh (187 1),18,
Robesonii
and
of Scientific
Discovery
(Bessels), 0.1 mm in dia (From reference 17).
in
K. A.
Mon.J.Microsc. 1, 32 (1869).
von
Zittel’s
59
60
Studies
function about
in the nutrition
Huxley’s
of the Protozoa’
discovery
coccoliths.21 The definitive
in History
(1875)
based on the latter’s
identification
of
the
and Philosophy
of Science
he expressed
doubts
misinterpretation
of the
coccoliths
was made
by
the
German biologist H. Lohmann in a monograph published in 1902. He identified the coccoliths as the settled fragments of the calcareous envelope of a class of flagellates to which he gave the name of Coccolithophoridae. 22 At the end of the year 1872 the ‘Challenger’ expedition had begun its program of soundings and dredgings in the three major ocean basins. During the early part of the itinerary many attempts were made by all the naturalists aboard to detect the presence of Bathybius in the fresh samples of deep-sea ooze, but without any success. However, one of the naturalists, J. Murray, noticed that when alcohol had been added to the ooze samples, Bathybius appeared. Moreover, when the chemist to the expedition, J. Y. Buchanan, made a chemical analysis of Bathybius, he failed to detect organic matter. Instead he found that Bathybius was composed of calcium sulphate which under certain conditions would crystallize as gypsum. He therefore suspected that Bathybius was nothing but calcium sulphate occurring in an amorphous colloidal state by the addition of alcohol to the ooze. This view was expressed by the chief scientist Wyville Thompson in a letter to Huxley dated June 1875.23 A full account was published by Murray in the ‘Preliminary in which he detailed the experiments conducted Reports’ (1876) aboard. ‘When
The results were these:
sea-water
is treated
of the amorphous When treated assumes
precipitate
with a great
a gelatinous
when
minutely
mixed
assumes excess
its volume
of spirit
the crystalline
of spirit
or less, nearly
the whole
form in a short time.
the precipitate
remains
amorphous,
and
aspect.
This gelatinous-like and
with twice
sulphate with
described
the
of lime colours ooze
has,
under
with the carmine the microscope,
and iodine solutions, the appearances
so
by Haeckel.’
‘When it is remembered that the original describers worked with spirit-preserved the inference seems fair that Bathybius and the specimens of the bottom, amorphous sulphate of lime are identical, and that in placing it amongst living things,
the describers
have committed
an error.‘%
Bathybius, Protobathybius Robesonii made its exit. The group of the Monera as such was retained in the zoological literature for several decades after. Gradually, however, forms such as Protamoeba primtiva became eliminated from the literature as they Together
With
2rG. C. Wallich, Ann Mag. nat. Hist. 16, 322 (1875). 22H. Lohmann, Arch. Protistenk. 1, p. 89 (1902). 23Quart. J. Microsc, SC. 15, 390 (1875). 24Proc. my. Sot. London 24,471 (1876).
Bathybius
Haeckelii
and the Psychology
were recognized
of Scientific
to be non-existent.
61
Discovery
H. F. Copeland
wrote in 1938
with
reference to Haeckel and the Monera: ‘He is said to have postulated, rather than to have recognized or assembled, such a group, because most of the organisms which he assigned to it, Protumoeba, and
Protomonus, definition.’
25
Vumpurella, and
Copeland,
are either non-existent or false to the have remore recently Whittaker,
assigned the term Monera to designate a Kingdom of procaryotic organisms, with unicellular or simple colonial organization. Reaction After receipt of Wyville Thompson’s letter, Huxley felt inclined to drop Bathybius as an imaginary discovery. Haeckel, however, refused to accept the results of the ‘Challenger’ expedition and he insisted on the actual existence of Bathybius. In a paper on ‘Bathybius und die Moneren’ (1877) he argued that its geographic distribution apparently was more limited than had been originally thought, and that consecruise had not been able to locate it.*’ quently the ‘Challenger’ Nevertheless, Haeckel eliminated Bathybius from his later publications. Little publicity was given to the Bathybius story after it had come to an end. This may explain why for example in a popular book on Modern Science and Modern Thought (1885; second edition 1886) written by S. Laing almost a decade after the ‘Challenger’ results had been obtained, Bathybius remained listed as the most primitive Moner. In the 1902 printing of this book the following paragraph occurs: ‘These monera deep 1868,
oceans,
are found where
and called
they
principally form
Bathybius.‘*
in the sea and in great masses at the bottom
a sort
of living slime first
described
by Huxley
of in
8
I have come across only one contemporary critical account of the Bathybius story, written by the French geologist A. de Lapparent who was an opponent of the theory of organic evolution. In his ‘Bathybius. Histoire d’un protoplasm’ (1878) he used the story to caution against biased research.2g In a more recent reference to Bathybius and Haeckel, W. Seifriz in his book on Protoplasm (1936) wrote with less caution: ‘Though his find was not what he though it to be, yet Haeckel’s philosophical idea is nevertheless sound, for we cannot escape the conviction that life began in a relatively undifferentiated mass of protoplasm.‘30 *5H_ F. Copeland Q. Rev. BioL 13, 383 (1938). 26 R H. Whittaker, *‘E. H. Haeckel, Entwicklungslehre 1, 26s. Laing, Modem 29.4. de Lapparent,
Science 163, 150 (1969). Kosmos. Zeitschrift fiil. Einheitliche Weltanschauung auf Grund der 293 (1877). Science and Modern Thought (Chapman & Hall, London, 1902) p. 79. Rev. Quest. Sci 3, 67 (1878).
Studies in History and Philosophy
62
Summary 1. The
fictitious
misinterpretation
discovery
contemporary
and Conclusions of Bathybius
of the mineral
dispersion by the addition misinterpretation of such scientists,
of Science
calcium
of alcohol enormity
in 1868
sulphate
was based
occurring
on a
in colloidal
to deep-sea ooze samples. A by several of the foremost
the quick and wide acceptance
of Bathybius
in
the life and earth sciences, the reconfirmation of its existence on several occasions, and the additional discovery of F’rotobathybius Robesonii, all could occur because the discovery was a corollary to the respected superstructure of evolutionary theory. 2. The original discovery of Bathybius was based on only a few samples of ooze dredged in the same general locality in the North Atlantic Ocean. The early reports that Bathybius had a near universal deep-sea distribution were based on the belief that it represented of its wide distribution in both primordial slime. Later reports present-day oceans and in the geologic record were based on the misinterpretation of coccoliths as tests of Bathybius. 3. The psychological factor of confidence in the heuristic value of evolutionary theory structured the discovery, the acceptance, and the silent exit of Bathybius Haeckelii.31
3O W. Seifriz, Aotoplasm (McGraw-Hill, New York, 1936) p. 11. 31Thanks go to Messrs. Hackmann, Ha&, Kuhn and McKerrow manuscript.
for critical reading of the
BATHYBIUS
A. RUPKE
HAECKELII
PSYCHOLOGY
AND
THE
OF SCIENTIFIC
DISCOVERY THEORY INSTEAD CONTROLLED THE ‘DISCOVERY’ FORM
OF OBSERVED DATA LATE 19th CENTURY OF A PRIMITIVE OF LIFE
THE TRADITIONAL image of the scientist as an objective fact finder has become seriously tarnished by recent work in the history and philosophy of science. ’ It is argued that the growth of science is not always brought about by a reasoned debate based on objective evidence. Instead, scientific discovery seems to be controlled quite as much by certain psychological factors such as respect for a theoretical superstructure. The debate around T. S. Kuhn’s The Structure of Scientific Revolutions has brought similar iconoclastic aspects of scientific conduct to the attention of a cross section of the scholarly community.’ Without wanting to enter into the controversy generated by Kuhn’s book,3 this paper records one of the better examples from the annals of science to show how respect for a theoretical superstructure brought about a fictitious the heuristic value century produced called Bathybius,
discovery. Specifically, it records how confidence in of evolutionary theory in the second half of the 19th the discovery of a fictitious primitive form of life, its sub-division into two genera, its reported occur-
rence over vast regions of the ocean floor, its identification in the geologic record, and its wide acceptance in the life and earth sciences for the period of almost a decade. Background Shortly
after the publication
to the ‘Discovery’
of Darwin’s
The Ongin
of Species
(1859),
1 See review paper by S. G. Brush, Science 183, 1164 (1974). 2T. S. Kuhn, The Structure of Scientific Reuolutions Univ. of Chicago Press, Chicago, 2nd edn., 1970. 3See for example Ctiticism nnd the Growth of Knowledge, I. Lakatos and A. Musgrave (eds.) Cambridge Univ. Press, Cambridge, 1970. Stud. Hist. Phil. Sci 7.( 1976), No. 1. Printed in Great Britain 53
54
Studies
the conceptual
in History
need was felt by a number
and Philosophy
of Darwin’s
of Science
supporters
to
link the late 18th century nebular hypothesis of planetary evolution with the hypothesis of organic evolution and establish by that the philosophy of ‘universal transformism’. The link was thought to consist of factual evidence for the origin of life out of inorganic matter, i.e. a&genesis.
Howeyer,
at about
the same time,
Pasteur
conducted
his
classic experiments on fermentation (1860-1866) and made a cogent case for the germ theory of fermentation and against abiogenesis. In the midst of the controversy generated by Pasteur’s experiments, the German zoologist E. H. Haeckel reported in his Generelle Morphologie der Organismen (1866) on the existence of a group of very primitive microbes, which he called Monera.’ A Moneron was defined as a primitive form of life consisting of undifferentiated protoplasm and lacking a nucleus. In a separate monograph on this group, Haeckel described in some detail a number of different Moneru, among which the most primitive of all which he called Protamoeba primitiu6 It was described as being entirely homogeneous and reproducing itself by process of binary fission (Figure 1). The primitive level of organization of the Monera was interpreted to indicate that the group represented life in statu nascendi, and as such it made abiogenesis conceivable.
Figure 1 Protamoeba
primitiva
(Haeckel), O-04 mm in dia (From reference 13).
The ‘Discovery’
of Bathybius
At about the same time that Haeckel announced the existence of the Moneru, the English zoologist T. H. Huxley examined a number (he did not mention how many) of mud samples dredged during an 1857 4L Pasteur, Ann Sci nut. Part. Zoo1 16, 5 (1861). SE. H. Haeckel, Generelle Mosphologie de7 Organismen 6E. H. Haeckel, Jenu Z Med Naturw. 4,64 (1868).
(Berlin, 1866) p. 135.
Bathybius Haeckeliiand
expedition
the Psychology of Scientific Discovery
aboard the ‘Cyclops’
northwest
55
of Ireland.
The mud samples
had been preserved in alcohol. Huxley, employing a special microscope with ‘a magnifying power of 1200 diameters’, 7 observed in the ooze a gelatinous protoplasm
substance with a granular texture. in a primitive state of organization
of Haeckel’s
Moneru.
In a paper
depths in the North Atlantic ‘I conceive they
are
that
the granule-heaps
imbedded
represent
the Radiolaria,
characterise
Ocean’
form
described
of those
by Haeckel
this new “Moner” Professor
simple
organisms
of protoplasm.
“Urschleim”,
animated
in his “Monographie name
in the University
beings
gelatinous Take
away
would
matter
in which
the cysts
very nearly
which
resemble
which must,
I think, be regarded
which
recently
have
der Moneren”.
of Bathybius, of Jena,
living at great
he wrote:
and a dead Sphaeroroum
the generic
of Zoology
(1868)
and the transparent
masses
one of the masses of this deep-sea a new
‘On some
He interpreted this as and identified it as one
I propose
been
to confer
and to call it after
B. Hueckelii
as
so well upon
the eminent
‘7
Inside the gelatinous substance Huxley identified two types of coccoliths which he called Cyatholithi and Discolithi. These he interpreted to be skeletal components of Bathybius Haeckelii, like spicules in sponges (Fig. 2).
Figure 2 Bathybius Haeckelii (Huxley),
O-1 mm in dia (From
reference
10).
Studies
56
The
existence
Thompson ‘Challenger’ Atlantic
of Bathybius
who later expedition.
Ocean
floor
in History and Philosophy
was confirmed
of Science
by Sir Charles
Wyville
was to become the chief scientist to the Thompson examined an ooze sample from the
and he remarked
in a paper ‘On the depths of the
sea’ (1869): ‘This
mud was actially
egg mixed sarcode.
alive; it stuck
with it; and the glairy
Prof.
Huxley
regards
together
in lumps,
mass proved,
this as a distinct
as if there
were white
under the microscope, creature,
of
to be a living
and calls it Bathybius.
”
In more detail Wyville Thompson described Bathybius in his classic of oceanography The Depths of the Sea ( 1873).9 In his ‘BeitrZge zur Plastidentheorie’ (1870), Haeckel exaggerated Huxley’s report by interpreting it to mean ‘that the sea floor of the open ocean at greater depths (below 5000 ft) is covered with enormous masses of free living protoplasm’.” He enthusiastically remarked that the discovery of Bathybius had turned the ‘Urschleim’ of the German ‘Naturphilosophie’ into a complete truth. Haeckel had himself obtained one sample of deep-sea mud, dredged by Wyville Thompson and W. B. Carpenter off the south-west coast of Ireland. The sample had been sent to him preserved in alcohol. Haeckel also observed the gelatinous substance with its granular texture which he coloured with a carmine solution and interpreted as real protoplasm. He thought it likely, though not entirely certain, that the coccoliths were skeletal components of Bathybius. Huxley accepted Haeckel’s exaggeration of his 1868 report and he added to this an exaggerated account of Haeckel’s description of Bathybius in a speech before the Royal Geographical Society in 1870. He said with respect to his by now reputed discovery: ‘Evidence Atlantic, forms This
of its existence and wherever
one continuous opinion
had published
has been
had been found the Indian
scum
of living matter
confirmed
an admirable
Ocean
account
throughout had been
the whole surveyed,
North
girding the whole surface
in all its essential of specimens
details
obtained
and South
so that it probably
by Prof.
of the earth. Haeckel,
who
by him.’ l1
The existence of masses of free protoplasm or ‘Urschleim’ on the sea floor was even more suggestive of a form of life in statu nascendi than Protamoeba primitiva. In a speech on ‘Das Leben in den griissten Meerestiefen’ (1870) Haeckel expressed the belief that it ‘was virtually certain that Bathybius originated by process of abiogenesis. More in general he argued that the question of the origin of life could not be 7T. H. Huxley, Quart. J. Microsc. London 8, 203 (1868). *c. W. Thompson, Ann Mug. nut. Hist. 4, 112 (1869). gC. W. Thompson, The Depths of the Sea (London, 1873) p. 410. 10~. H. Haeckel, Jena. Z Med Naturw. 5, 492 (1870). 11~. H. Huxley, Proc. R geogrl. Sot. 15, 37 (1871).
Bathybius
Haeckeliiand
solved
by
through
the Psychology
experiment
(an
a philosophical
The discovery
of Scientific
apparent
57
Discovery
reference
to Pasteur),
but
only
approach. l2
of Bathybius
and of the other Monera
established
the
link between planetary evolution and organic evolution. In his widely read Natiirliche Sch6pf&zgsgeschichte (1870) Haeckel explicitly wrote: ‘Whenever result
previously
of the organic
at the time.
This main problem
the extremely that
are
one tried
important
not
and that
abiogenesis
has gained
between originates
Kant’s known
such
only since we have understood of
organs,
feed,
a degree
that
consist
and reproduce.
and Lamarck’s
is the marvellous
a single
of evolution. Bathybius
chemical
the hypothesis
as to entitle
one type exists which still today This
theory
of just
cosmogeny
to know
them as organisms
As a result,
of probability
faiied as a
that one knew
has been solved only since we have become
up till now,
by abiogenesis.
and described
up
still grow,
one immediately
abiogenesis,
of even the most simple organisms
Monera,
at all made
compound,
Monera
to visualize
composition
of
it to fill the gap
Already
probably Haeckelii,
among
the
continuously discovered
by Huxley.‘13
The Bathybius
bandwagon
The discovery of Bathybius Haeckelii generated a great deal of excitement in the life and earth sciences and a number of biologists and geologists continued the investigation of this Moneron. The German biologist 0. Schmidt reported in a paper ‘uber Coccolithen and Rhabdolithen’ (1870) that in the course of an oceanoLgraphic expedition in the Adriatic Sea he had found evidence of the existence of Bathybius there as well. In addition, he reported that he had observed Bathybius in ooze samples that had no alcohol added to them (‘Der frisch aus dem Meere gehobene Bathybius zeigt . . . genau jene Erscheinungen, welche die in Weingeist conservirten Proben wahrnehmen lassen.‘) l4 In addition to the coccoliths, he observed more rod-shaped particles which he called rhabdoliths. He however did not believe that they were part of Bathybius. In the same year, the German geologist C. W. von Gtimbel published the results of his study of a number of deep-sea mud samples, also In his preserved in alcohol. ‘Vorlaufige Mitteilungen iiber Tiefseeschlamm’ ( 1870) h e concluded, in support of the work by Huxley and Haeckel, that Bathybius with its coccoliths formed a living substance. In addition, he reported that its occurrence was not confined to the bathyal environment, but that it existed also in shallower marine environments and all around the world (‘. . . dass Coccolithen ’ 2E. I% Haeckel, Snmmlung Gemeinversth’ndlicher Wissenschaftlicher Vortriige, Heft 140, 1 (1870). t3E. H. Haeckel, Natiirliche SchGpfutagsgeschichte (Berlin, 1870), p. 306. Quote translated from the German. t40. Schmidt, Sitzungsber. Kaberl. Akad Wiss. Wien Math Natunu. K. 62. 669 (1870).
58
Studies
and Philosophy
of Science
in allen Meeren und in allen Meerestiefen vorkommen’).” of the fact that coccoliths occur in many limestones as had
(Bathybius) On account been
in History
established
emphasized
by
the
English
the lithogenetic
geologist
importance
H. C.
Sorby,
of Bathybius
Giimbel
in the geologic
record. Earlier on, immediately after Huxley’s discovery, Bathybius had been identified in the geologic record by the English geologist W. B. Carpenter. At that time a controversy existed with respect to an inorganic banded structure of ophicalcites in Precambrian rocks in Canada. The Canadian geologist J. W. Dawson interpreted these structures as organic, produced by a gigantic foraminifer, which he called
Eozoiin
In support
Canadense.
of Dawson’s
organic
interpret-
ation, Carpenter cited the discovery of Bathybius thinking it likely that it had existed through all of geologic time and that, if it had developed a shell, it would have resembled Eozoiin Canadense. (‘. . . if Bathybius, like the testaceous Rhizopods, could form for itself a shelly envelope, that envelope would closely resemble Eozoijn. Further, as Prof. Huxley has proved the existence of Bathybius through a great range, not merely of depth but of temperature, I cannot but think it probable that it has existed continuously in the deep seas of all geological epochs.‘)“j A still lower Moner than Bathybius was discovered in 1874 along the coast of Grinnell Land by the U.S. Arctic expedition aboard the ‘Polaris’. The discovery was made by the German E. Bessels, surgeon and naturalist to the expedition. It was characterized by the absence of coccoliths, and its movements were described as amoeboid. Bessels called it Protobathybius Robesonii and he reported his discovery in Nature (1874). A description of it was also included in A. S. Packard’s Life Histories of Animals (1876) (Figure 3): ‘It is mainly
distinguished
and the Cyatholithes. whence
the
intensily
name
drops,
given
by a solution
considerable soluble
particles
refracting in ether.
of carmine
from
Bathybius
For this reason
to it. It consists of carmine power,
foreign
of nearly
in ammonia.
and besides
It manifests
or other
by the absence
of both
I take it to be an older form
very
marked
substances
pure protoplasm,
It contains
the latter
the Discolithes than Bathybius,
a great
amoeboid suspended
tinged
most
fine gray granules
of
number
of oleaginous
motions
and takes up
in the water in which it
is kept.“’
This paper is not intended as a bibliography of Bathybius Haeckelii. Suffice therefore to mention that the discovery was reported in such influential publications as the Archives des Sciences Physiques et i ‘C. W. van Giimbel, N. Jb. Miner. Geol. Palaeont. 753 (1870). 16~. B. Carpenter, Proc. R. Sot. London 17 191 (1868). 1 ‘A. S. Packard, Life Histories of Animals (New York, 1876) p. 3.
Bathybius
Haeckelii
and the Psychology
Figure 3 Protobathybius
ZVutureZh (187 1),18,
Robesonii
and
of Scientific
Discovery
(Bessels), 0.1 mm in dia (From reference 17).
in
K. A.
Mon.J.Microsc. 1, 32 (1869).
von
Zittel’s
59
60
Studies
function about
in the nutrition
Huxley’s
of the Protozoa’
discovery
coccoliths.21 The definitive
in History
(1875)
based on the latter’s
identification
of
the
and Philosophy
of Science
he expressed
doubts
misinterpretation
of the
coccoliths
was made
by
the
German biologist H. Lohmann in a monograph published in 1902. He identified the coccoliths as the settled fragments of the calcareous envelope of a class of flagellates to which he gave the name of Coccolithophoridae. 22 At the end of the year 1872 the ‘Challenger’ expedition had begun its program of soundings and dredgings in the three major ocean basins. During the early part of the itinerary many attempts were made by all the naturalists aboard to detect the presence of Bathybius in the fresh samples of deep-sea ooze, but without any success. However, one of the naturalists, J. Murray, noticed that when alcohol had been added to the ooze samples, Bathybius appeared. Moreover, when the chemist to the expedition, J. Y. Buchanan, made a chemical analysis of Bathybius, he failed to detect organic matter. Instead he found that Bathybius was composed of calcium sulphate which under certain conditions would crystallize as gypsum. He therefore suspected that Bathybius was nothing but calcium sulphate occurring in an amorphous colloidal state by the addition of alcohol to the ooze. This view was expressed by the chief scientist Wyville Thompson in a letter to Huxley dated June 1875.23 A full account was published by Murray in the ‘Preliminary in which he detailed the experiments conducted Reports’ (1876) aboard. ‘When
The results were these:
sea-water
is treated
of the amorphous When treated assumes
precipitate
with a great
a gelatinous
when
minutely
mixed
assumes excess
its volume
of spirit
the crystalline
of spirit
or less, nearly
the whole
form in a short time.
the precipitate
remains
amorphous,
and
aspect.
This gelatinous-like and
with twice
sulphate with
described
the
of lime colours ooze
has,
under
with the carmine the microscope,
and iodine solutions, the appearances
so
by Haeckel.’
‘When it is remembered that the original describers worked with spirit-preserved the inference seems fair that Bathybius and the specimens of the bottom, amorphous sulphate of lime are identical, and that in placing it amongst living things,
the describers
have committed
an error.‘%
Bathybius, Protobathybius Robesonii made its exit. The group of the Monera as such was retained in the zoological literature for several decades after. Gradually, however, forms such as Protamoeba primtiva became eliminated from the literature as they Together
With
2rG. C. Wallich, Ann Mag. nat. Hist. 16, 322 (1875). 22H. Lohmann, Arch. Protistenk. 1, p. 89 (1902). 23Quart. J. Microsc, SC. 15, 390 (1875). 24Proc. my. Sot. London 24,471 (1876).
Bathybius
Haeckelii
and the Psychology
were recognized
of Scientific
to be non-existent.
61
Discovery
H. F. Copeland
wrote in 1938
with
reference to Haeckel and the Monera: ‘He is said to have postulated, rather than to have recognized or assembled, such a group, because most of the organisms which he assigned to it, Protumoeba, and
Protomonus, definition.’
25
Vumpurella, and
Copeland,
are either non-existent or false to the have remore recently Whittaker,
assigned the term Monera to designate a Kingdom of procaryotic organisms, with unicellular or simple colonial organization. Reaction After receipt of Wyville Thompson’s letter, Huxley felt inclined to drop Bathybius as an imaginary discovery. Haeckel, however, refused to accept the results of the ‘Challenger’ expedition and he insisted on the actual existence of Bathybius. In a paper on ‘Bathybius und die Moneren’ (1877) he argued that its geographic distribution apparently was more limited than had been originally thought, and that consecruise had not been able to locate it.*’ quently the ‘Challenger’ Nevertheless, Haeckel eliminated Bathybius from his later publications. Little publicity was given to the Bathybius story after it had come to an end. This may explain why for example in a popular book on Modern Science and Modern Thought (1885; second edition 1886) written by S. Laing almost a decade after the ‘Challenger’ results had been obtained, Bathybius remained listed as the most primitive Moner. In the 1902 printing of this book the following paragraph occurs: ‘These monera deep 1868,
oceans,
are found where
and called
they
principally form
Bathybius.‘*
in the sea and in great masses at the bottom
a sort
of living slime first
described
by Huxley
of in
8
I have come across only one contemporary critical account of the Bathybius story, written by the French geologist A. de Lapparent who was an opponent of the theory of organic evolution. In his ‘Bathybius. Histoire d’un protoplasm’ (1878) he used the story to caution against biased research.2g In a more recent reference to Bathybius and Haeckel, W. Seifriz in his book on Protoplasm (1936) wrote with less caution: ‘Though his find was not what he though it to be, yet Haeckel’s philosophical idea is nevertheless sound, for we cannot escape the conviction that life began in a relatively undifferentiated mass of protoplasm.‘30 *5H_ F. Copeland Q. Rev. BioL 13, 383 (1938). 26 R H. Whittaker, *‘E. H. Haeckel, Entwicklungslehre 1, 26s. Laing, Modem 29.4. de Lapparent,
Science 163, 150 (1969). Kosmos. Zeitschrift fiil. Einheitliche Weltanschauung auf Grund der 293 (1877). Science and Modern Thought (Chapman & Hall, London, 1902) p. 79. Rev. Quest. Sci 3, 67 (1878).
Studies in History and Philosophy
62
Summary 1. The
fictitious
misinterpretation
discovery
contemporary
and Conclusions of Bathybius
of the mineral
dispersion by the addition misinterpretation of such scientists,
of Science
calcium
of alcohol enormity
in 1868
sulphate
was based
occurring
on a
in colloidal
to deep-sea ooze samples. A by several of the foremost
the quick and wide acceptance
of Bathybius
in
the life and earth sciences, the reconfirmation of its existence on several occasions, and the additional discovery of F’rotobathybius Robesonii, all could occur because the discovery was a corollary to the respected superstructure of evolutionary theory. 2. The original discovery of Bathybius was based on only a few samples of ooze dredged in the same general locality in the North Atlantic Ocean. The early reports that Bathybius had a near universal deep-sea distribution were based on the belief that it represented of its wide distribution in both primordial slime. Later reports present-day oceans and in the geologic record were based on the misinterpretation of coccoliths as tests of Bathybius. 3. The psychological factor of confidence in the heuristic value of evolutionary theory structured the discovery, the acceptance, and the silent exit of Bathybius Haeckelii.31
3O W. Seifriz, Aotoplasm (McGraw-Hill, New York, 1936) p. 11. 31Thanks go to Messrs. Hackmann, Ha&, Kuhn and McKerrow manuscript.
for critical reading of the