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Oversikt over mellomledd
| PERIODE |
Epoke |
Fisk til amfibie |
Amfibie til reptil |
Cretaceous
(146 to 65 mya) |
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Jurassic
(208 to 146 mya) |
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Triassic
(245 to 208 mya) |
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Permian
(286 to 245 mya) |
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Carboniferous
(360 to 286 mya) |
Pennsylvanian
(325 to 286 mya) |
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Hylonomus, Paleothyris (early
Pennsylvanian) -- These are protorothyrids, very early cotylosaurs
(primitive reptiles). They were quite little, lizard-sized animals
with amphibian-like skulls (amphibian pineal opening, dermal bone,
etc.), shoulder, pelvis, & limbs, and intermediate teeth and vertebrae.
Rest of skeleton reptilian, with reptilian jaw muscle, no palatal
fangs, and spool-shaped vertebral centra. Probably no eardrum yet.
Many of these new "reptilian" features are also seen in little
amphibians (which also sometimes have direct-developing eggs laid
on land), so perhaps these features just came along with the small
body size of the first reptiles.
Limnoscelis, Tseajaia (late Carboniferous)
-- Amphibians apparently derived from the early anthracosaurs, but
with additional reptilian features: structure of braincase, reptilian
jaw muscle, expanded neural arches. |
Mississippian
(360 to 325 mya) |
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Proterogyrinus or another early anthracosaur
(late Mississippian) -- Classic labyrinthodont-amphibian skull and
teeth, but with reptilian vertebrae, pelvis, humerus, and digits.
Still has fish skull hinge. Amphibian ankle. 5-toed hand and a 2-3-4-5-3
(almost reptilian) phalangeal count. |
| Devonian
(410 to 360 mya) |
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Fragmented limbs and
teeth from the middle Late Devonian (about 370 Ma), possibly belonging
to Obruchevichthys -- Discovered in 1991 in Scotland,
these are the earliest known tetrapod remains. The humerus is mostly
tetrapod-like but retains some fish features. The discoverer, Ahlberg
(1991), said: "It [the humerus] is more tetrapod-like than any fish
humerus, but lacks the characteristic early tetrapod 'L-shape'...this
seems to be a primitive, fish-like character....although the tibia
clearly belongs to a leg, the humerus differs enough from the early
tetrapod pattern to make it uncertain whether the appendage carried
digits or a fin. At first sight the combination of two such extremities
in the same animal seems highly unlikely on functional grounds. If,
however, tetrapod limbs evolved for aquatic rather than terrestrial
locomotion, as recently suggested, such a morphology might be perfectly
workable." Panderichthys, Elpistostege
(mid-late Devonian, about 370 Ma) -- These "panderichthyids" are
very tetrapod-like lobe-finned fish. Unlike Eusthenopteron,
these fish actually look like tetrapods in overall proportions (flattened
bodies, dorsally placed orbits, frontal bones! in the skull, straight
tails, etc.) and have remarkably foot-like fins.
Eusthenopteron, Sterropterygion (mid-late
Devonian) -- Early rhipidistian lobe-finned fish roughly intermediate
between early crossopterygian fish and the earliest amphibians.
Eusthenopteron is best known, from an unusually complete
fossil first found in 1881. Skull very amphibian-like. Strong amphibian-
like backbone. Fins very like early amphibian feet in the overall
layout of the major bones, muscle attachments, and bone processes,
with tetrapod-like tetrahedral humerus, and tetrapod-like elbow
and knee joints. But there are no perceptible "toes", just a set
of identical fin rays. Body & skull proportions rather fishlike.
Osteolepis (mid-Devonian) -- One of the earliest
crossopterygian lobe-finned fishes, still sharing some characters
with the lungfish (the other lobe-finned fishes). Had paired fins
with a leg-like arrangement of major limb bones, capable of flexing
at the "elbow", and had an early-amphibian-like skull and teeth. |
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Reptil til pattedyr
- Paleothyris (early Pennsylvanian) -- An early captorhinomorph
reptile, with no temporal fenestrae at all.
- Protoclepsydrops haplous (early Pennsylvanian) -- The
earliest known synapsid reptile. Little temporal fenestra, with all surrounding
bones intact. Fragmentary. Had amphibian-type vertebrae with tiny neural
processes. (reptiles had only just separated from the amphibians)
- Clepsydrops (early Pennsylvanian) -- The second earliest
known synapsid. These early, very primitive synapsids are a primitive
group of pelycosaurs collectively called "ophiacodonts".
- Archaeothyris (early-mid Pennsylvanian) -- A slightly
later ophiacodont. Small temporal fenestra, now with some reduced bones
(supratemporal). Braincase still just loosely attached to skull. Slight
hint of different tooth types. Still has some extremely primitive, amphibian/captorhinid
features in the jaw, foot, and skull. Limbs, posture, etc. typically reptilian,
though the ilium (major hip bone) was slightly enlarged.
- Varanops (early Permian) -- Temporal fenestra further
enlarged. Braincase floor shows first mammalian tendencies & first
signs of stronger attachment to rest of skull (occiput more strongly attached).
Lower jaw shows first changes in jaw musculature (slight coronoid eminence).
Body narrower, deeper: vertebral column more strongly constructed. Ilium
further enlarged, lower-limb musculature starts to change (prominent fourth
trochanter on femur). This animal was more mobile and active. Too late
to be a true ancestor, and must be a "cousin".
- Haptodus (late Pennsylvanian) -- One of the first known
sphenacodonts, showing the initiation of sphenacodont features while retaining
many primitive features of the ophiacodonts. Occiput still more strongly
attached to the braincase. Teeth become size-differentiated, with biggest
teeth in canine region and fewer teeth overall. Stronger jaw muscles.
Vertebrae parts & joints more mammalian. Neural spines on vertebrae
longer. Hip strengthened by fusing to three sacral vertebrae instead of
just two. Limbs very well developed.
- Dimetrodon, Sphenacodon or a similar sphenacodont
(late Pennsylvanian to early Permian, 270 Ma) -- More advanced pelycosaurs,
clearly closely related to the first therapsids (next). Dimetrodon
is almost definitely a "cousin" and not a direct ancestor, but as it is
known from very complete fossils, it's a good model for sphenacodont anatomy.
Medium-sized fenestra. Teeth further differentiated, with small incisors,
two huge deep- rooted upper canines on each side, followed by smaller
cheek teeth, all replaced continuously. Fully reptilian jaw hinge. Lower
jaw bone made of multiple bones & with first signs of a bony prong
later involved in the eardrum, but there was no eardrum yet, so these
reptiles could only hear ground-borne vibrations (they did have a reptilian
middle ear). Vertebrae had still longer neural spines (spectacularly so
in Dimetrodon, which had a sail), and longer transverse
spines for stronger locomotion muscles.
- Biarmosuchia (late Permian) -- A therocephalian -- one
of the earliest, most primitive therapsids. Several primitive, sphenacodontid
features retained: jaw muscles inside the skull, platelike occiput, palatal
teeth. New features: Temporal fenestra further enlarged, occupying virtually
all of the cheek, with the supratemporal bone completely gone. Occipital
plate slanted slightly backwards rather than forwards as in pelycosaurs,
and attached still more strongly to the braincase. Upper jaw bone (maxillary)
expanded to separate lacrymal from nasal bones, intermediate between early
reptiles and later mammals. Still no secondary palate, but the
vomer bones of the palate developed a backward extension below the palatine
bones. This is the first step toward a secondary palate, and with exactly
the same pattern seen in cynodonts. Canine teeth larger, dominating the
dentition. Variable tooth replacement: some therocephalians (e.g Scylacosaurus)
had just one canine, like mammals, and stopped replacing the canine after
reaching adult size. Jaw hinge more mammalian in position and shape, jaw
musculature stronger (especially the mammalian jaw muscle). The amphibian-like
hinged upper jaw finally became immovable. Vertebrae still sphenacodontid-like.
Radical alteration in the method of locomotion, with a much more mobile
forelimb, more upright hindlimb, & more mammalian femur & pelvis.
Primitive sphenacodontid humerus. The toes were approaching equal length,
as in mammals, with #toe bones varying from reptilian to mammalian. The
neck & tail vertebrae became distinctly different from trunk vertebrae.
Probably had an eardrum in the lower jaw, by the jaw hinge.
- Procynosuchus (latest Permian) -- The first known cynodont
-- a famous group of very mammal-like therapsid reptiles, sometimes considered
to be the first mammals. Probably arose from the therocephalians, judging
from the distinctive secondary palate and numerous other skull characters.
Enormous temporal fossae for very strong jaw muscles, formed by just one
of the reptilian jaw muscles, which has now become the mammalian masseter.
The large fossae is now bounded only by the thin zygomatic arch (cheekbone
to you & me). Secondary palate now composed mainly of palatine bones
(mammalian), rather than vomers and maxilla as in older forms; it's still
only a partial bony palate (completed in life with soft tissue). Lower
incisor teeth was reduced to four (per side), instead of the previous
six (early mammals had three). Dentary now is 3/4 of lower jaw; the other
bones are now a small complex near the jaw hinge. Jaw hinge still reptilian.
Vertebral column starts to look mammalian: first two vertebrae modified
for head movements, and lumbar vertebrae start to lose ribs, the first
sign of functional division into thoracic and lumbar regions. Scapula
beginning to change shape. Further enlargement of the ilium and reduction
of the pubis in the hip. A diaphragm may have been present.
- Dvinia [also "Permocynodon"] (latest Permian) -- Another
early cynodont. First signs of teeth that are more than simple stabbing
points -- cheek teeth develop a tiny cusp. The temporal fenestra increased
still further. Various changes in the floor of the braincase; enlarged
brain. The dentary bone was now the major bone of the lower jaw. The other
jaw bones that had been present in early reptiles were reduced to a complex
of smaller bones near the jaw hinge. Single occipital condyle splitting
into two surfaces. The postcranial skeleton of Dvinia is virtually unknown
and it is not therefore certain whether the typical features found at
the next level had already evolved by this one. Metabolic rate was probably
increased, at least approaching homeothermy.
- Thrinaxodon (early Triassic) -- A more advanced "galesaurid"
cynodont. Further development of several of the cynodont features seen
already. Temporal fenestra still larger, larger jaw muscle attachments.
Bony secondary palate almost complete. Functional division of teeth: incisors
(four uppers and three lowers), canines, and then 7-9 cheek teeth with
cusps for chewing. The cheek teeth were all alike, though (no premolars
& molars), did not occlude together, were all single- rooted, and
were replaced throughout life in alternate waves. Dentary still larger,
with the little quadrate and articular bones were loosely attached. The
stapes now touched the inner side of the quadrate. First sign of the mammalian
jaw hinge, a ligamentous connection between the lower jaw and the squamosal
bone of the skull. The occipital condyle is now two slightly separated
surfaces, though not separated as far as the mammalian double condyles.
Vertebral connections more mammalian, and lumbar ribs reduced. Scapula
shows development of a new mammalian shoulder muscle. Ilium increased
again, and all four legs fully upright, not sprawling. Tail short, as
is necessary for agile quadrupedal locomotion. The whole locomotion was
more agile. Number of toe bones is 2.3.4.4.3, intermediate between reptile
number (2.3.4.5.4) and mammalian (2.3.3.3.3), and the "extra" toe bones
were tiny. Nearly complete skeletons of these animals have been found
curled up - a possible reaction to conserve heat, indicating possible
endothermy? Adults and juveniles have been found together, possibly a
sign of parental care. The specialization of the lumbar area (e.g. reduction
of ribs) is indicative of the presence of a diaphragm, needed for higher
O2 intake and homeothermy. NOTE on hearing: The eardrum had developed
in the only place available for it -- the lower jaw, right near
the jaw hinge, supported by a wide prong (reflected lamina) of the angular
bone. These animals could now hear airborne sound, transmitted through
the eardrum to two small lower jaw bones, the articular and the quadrate,
which contacted the stapes in the skull, which contacted the cochlea.
Rather a roundabout system and sensitive to low-frequency sound only,
but better than no eardrum at all! Cynodonts developed quite loose quadrates
and articulars that could vibrate freely for sound transmittal while still
functioning as a jaw joint, strengthened by the mammalian jaw joint right
next to it. All early mammals from the Lower Jurassic have this low-frequency
ear and a double jaw joint. By the middle Jurassic, mammals lost the reptilian
joint (though it still occurs briefly in embryos) and the two bones moved
into the nearby middle ear, became smaller, and became much more sensitive
to high-frequency sounds.
- Cynognathus (early Triassic, 240 Ma; suspected to have
existed even earlier) -- We're now at advanced cynodont level. Temporal
fenestra larger. Teeth differentiating further; cheek teeth with cusps
met in true occlusion for slicing up food, rate of replacement reduced,
with mammalian-style tooth roots (though single roots). Dentary still
larger, forming 90% of the muscle-bearing part of the lower jaw. TWO JAW
JOINTS in place, mammalian and reptilian: A new bony jaw joint existed
between the squamosal (skull) and the surangular bone (lower jaw), while
the other jaw joint bones were reduced to a compound rod lying in a trough
in the dentary, close to the middle ear. Ribs more mammalian. Scapula
halfway to the mammalian condition. Limbs were held under body. There
is possible evidence for fur in fossil pawprints.
- Diademodon (early Triassic, 240 Ma; same strata as Cynognathus)
-- Temporal fenestra larger still, for still stronger jaw muscles. True
bony secondary palate formed exactly as in mammals, but didn't extend
quite as far back. Turbinate bones possibly present in the nose (warm-blooded?).
Dental changes continue: rate of tooth replacement had decreased, cheek
teeth have better cusps & consistent wear facets (better occlusion).
Lower jaw almost entirely dentary, with tiny articular at the hinge. Still
a double jaw joint. Ribs shorten suddenly in lumbar region, probably improving
diaphragm function & locomotion. Mammalian toe bones (2.3.3.3.3),
with closely related species still showing variable numbers.
- Probelesodon (mid-Triassic; South America) -- Fenestra
very large, still separate from eyesocket (with postorbital bar). Secondary
palate longer, but still not complete. Teeth double-rooted, as in mammals.
Nares separated. Second jaw joint stronger. Lumbar ribs totally lost;
thoracic ribs more mammalian, vertebral connections very mammalian. Hip
& femur more mammalian.
- Probainognathus (mid-Triassic, 239-235 Ma, Argentina)
-- Larger brain with various skull changes: pineal foramen ("third eye")
closes, fusion of some skull plates. Cheekbone slender, low down on the
side of the eye socket. Postorbital bar still there. Additional cusps
on cheek teeth. Still two jaw joints. Still had cervical ribs & lumbar
ribs, but they were very short. Reptilian "costal plates" on thoracic
ribs mostly lost. Mammalian #toe bones.
- Exaeretodon (mid-late Triassic, 239Ma, South America)
-- (Formerly lumped with the herbivorous gomphodont cynodonts.) Mammalian
jaw prong forms, related to eardrum support. Three incisors only (mammalian).
Costal plates completely lost. More mammalian hip related to having limbs
under the body. Possibly the first steps toward coupling of locomotion
& breathing. This is probably a "cousin" fossil not directly ancestral,
as it has several new but non-mammalian teeth traits.
GAP of about 30 my in the late Triassic, from about 239-208 Ma. Only one
early mammal fossil is known from this time. The next time fossils are found
in any abundance, tritylodontids and trithelodontids had already appeared,
leading to some very heated controversy about their relative placement in
the chain to mammals. Recent discoveries seem to show trithelodontids to
be more mammal- like, with tritylodontids possibly being an offshoot group
(see Hopson 1991, Rowe 1988, Wible 1991, and Shubin et al. 1991). Bear in
mind that both these groups were almost fully mammalian in every feature,
lacking only the final changes in the jaw joint and middle ear.
- Oligokyphus, Kayentatherium (early Jurassic,
208 Ma) -- These are tritylodontids, an advanced cynodont group. Face
more mammalian, with changes around eyesocket and cheekbone. Full bony
secondary palate. Alternate tooth replacement with double-rooted cheek
teeth, but without mammalian-style tooth occlusion (which some
earlier cynodonts already had). Skeleton strikingly like egg- laying mammals
(monotremes). Double jaw joint. More flexible neck, with mammalian atlas
& axis and double occipital condyle. Tail vertebrae simpler, like
mammals. Scapula is now substantially mammalian, and the forelimb is carried
directly under the body. Various changes in the pelvis bones and hind
limb muscles; this animal's limb musculature and locomotion were virtually
fully mammalian. Probably cousin fossils (?), with Oligokyphus
being more primitive than Kayentatherium. Thought to have diverged
from the trithelodontids during that gap in the late Triassic. There is
disagreement about whether the tritylodontids were ancestral to mammals
(presumably during the late Triassic gap) or whether they are a specialized
offshoot group not directly ancestral to mammals.
- Pachygenelus, Diarthrognathus (earliest
Jurassic, 209 Ma) -- These are trithelodontids, a slightly different advanced
cynodont group. New discoveries (Shubin et al., 1991) show that these
animals are very close to the ancestry of mammals. Inflation of nasal
cavity, establishment of Eustachian tubes between ear and pharynx, loss
of postorbital bar. Alternate replacement of mostly single- rooted teeth.
This group also began to develop double tooth roots -- in Pachygenelus
the single root of the cheek teeth begins to split in two at the base.
Pachygenelus also has mammalian tooth enamel, and mammalian tooth
occlusion. Double jaw joint, with the second joint now a dentary-squamosal
(instead of surangular), fully mammalian. Incipient dentary condyle. Reptilian
jaw joint still present but functioning almost entirely in hearing; postdentary
bones further reduced to tiny rod of bones in jaw near middle ear; probably
could hear high frequencies now. More mammalian neck vertebrae for a flexible
neck. Hip more mammalian, with a very mammalian iliac blade & femur.
Highly mobile, mammalian-style shoulder. Probably had coupled locomotion
& breathing. These are probably "cousin" fossils, not directly ancestral
(the true ancestor is thought to have occurred during that late Triassic
gap). Pachygenelus is pretty close, though.
- Adelobasileus cromptoni (late Triassic; 225 Ma,
west Texas) -- A recently discovered fossil proto-mammal from right in
the middle of that late Triassic gap! Currently the oldest known "mammal."
Only the skull was found. "Some cranial features of Adelobasileus,
such as the incipient promontorium housing the cochlea, represent an intermediate
stage of the character transformation from non-mammalian cynodonts to
Liassic mammals" (Lucas & Luo, 1993). This fossil was found from a
band of strata in the western U.S. that had not previously been studied
for early mammals. Also note that this fossil dates from slightly before
the known tritylodonts and trithelodonts, though it has long been suspected
that tritilodonts and trithelodonts were already around by then. Adelobasileus
is thought to have split off from either a trityl. or a trithel., and
is either identical to or closely related to the common ancestor of all
mammals.
- Sinoconodon (early Jurassic, 208 Ma) -- The next known
very ancient proto-mammal. Eyesocket fully mammalian now (closed medial
wall). Hindbrain expanded. Permanent cheekteeth, like mammals, but the
other teeth were still replaced several times. Mammalian jaw joint stronger,
with large dentary condyle fitting into a distinct fossa on the squamosal.
This final refinement of the joint automatically makes this animal a true
"mammal". Reptilian jaw joint still present, though tiny.
- Kuehneotherium (early Jurassic, about 205 Ma) -- A slightly
later proto-mammal, sometimes considered the first known pantothere (primitive
placental-type mammal). Teeth and skull like a placental mammal. The three
major cusps on the upper & lower molars were rotated to form interlocking
shearing triangles as in the more advanced placental mammals & marsupials.
Still has a double jaw joint, though.
- Eozostrodon, Morganucodon, Haldanodon
(early Jurassic, ~205 Ma) -- A group of early proto-mammals called "morganucodonts".
The restructuring of the secondary palate and the floor of the braincase
had continued, and was now very mammalian. Truly mammalian teeth: the
cheek teeth were finally differentiated into simple premolars and more
complex molars, and teeth were replaced only once. Triangular- cusped
molars. Reversal of the previous trend toward reduced incisors, with lower
incisors increasing to four. Tiny remnant of the reptilian jaw joint.
Once thought to be ancestral to monotremes only, but now thought to be
ancestral to all three groups of modern mammals -- monotremes, marsupials,
and placentals.
- Peramus (late Jurassic, about 155 Ma) -- A "eupantothere"
(more advanced placental-type mammal). The closest known relative of the
placentals & marsupials. Triconodont molar has with more defined cusps.
This fossil is known only from teeth, but judging from closely related
eupantotheres (e.g. Amphitherium) it had finally lost the reptilian
jaw joint, attaing a fully mammalian three-boned middle ear with excellent
high-frequency hearing. Has only 8 cheek teeth, less than other eupantotheres
and close to the 7 of the first placental mammals. Also has a large talonid
on its "tribosphenic" molars, almost as large as that of the first placentals
-- the first development of grinding capability.
- Endotherium (very latest Jurassic, 147 Ma) -- An advanced
eupantothere. Fully tribosphenic molars with a well- developed talonid.
Known only from one specimen. From Asia; recent fossil finds in Asia suggest
that the tribosphenic molar evolved there.
- Kielantherium and Aegialodon (early Cretaceous)
-- More advanced eupantotheres known only from teeth. Kielantherium
is from Asia and is known from slightly older strata than the European
Aegialodon. Both have the talonid on the lower molars. The wear
on it indicates that a major new cusp, the protocone, had evolved on the
upper molars. By the Middle Cretaceous, animals with the new tribosphenic
molar had spread into North America too (North America was still connected
to Europe.)
- Steropodon galmani (early Cretaceous) -- The first
known definite monotreme, discovered in 1985.
- Vincelestes neuquenianus (early Cretaceous, 135
Ma) -- A probably-placental mammal with some marsupial traits, known from
some nice skulls. Placental-type braincase and coiled cochlea. Its intracranial
arteries & veins ran in a composite monotreme/placental pattern derived
from homologous extracranial vessels in the cynodonts. (Rougier et al.,
1992)
- Pariadens kirklandi (late Cretaceous, about 95
Ma) -- The first definite marsupial. Known only from teeth.
- Kennalestes and Asioryctes (late Cretaceous,
Mongolia) -- Small, slender animals; eyesocket open behind; simple ring
to support eardrum; primitive placental-type brain with large olfactory
bulbs; basic primitive tribosphenic tooth pattern. Canine now double rooted.
Still just a trace of a non-dentary bone, the coronoid, on the otherwise
all-dentary jaw. "Could have given rise to nearly all subsequent placentals."
says Carroll (1988).
- Cimolestes, Procerberus, Gypsonictops
(very late Cretaceous) -- Primitive North American placentals with same
basic tooth pattern.
Kilder
Transitional
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