Skull openings , in the skull behind each eye. This schematic shows the skull viewed from the left side. The middle opening is the orbit of the eye; the opening to the right of it is the temporal fenestra. Synapsids evolved a
temporal fenestra behind each eye
orbit on the lateral surface of the skull. It may have provided new attachment sites for jaw muscles. Originally, the openings in the skull left the inner cranium covered only by the jaw muscles, but in higher therapsids and mammals, the
sphenoid bone has expanded to close the opening. This has left the lower margin of the opening as an arch extending from the lower edges of the braincase. While historically argued to be distinctive to synapsids, recent research has demonstrated that many primitive sauropsids also have a single lower temporal fenestra and it has also been suggested that many thought to be sauropsids with
anapsid skulls completely lacking temporal fenestrae are not reptiles but stem-amniotes, implying that this trait was possibly present in the last common ancestor of synapsids and sauropsids, and not a distinctive trait of Synapsida.
Teeth '', an early synapsid with multiple canines Synapsids are characterized by having
differentiated teeth. These include the
canines,
molars, and
incisors. The trend towards differentiation is found in some
labyrinthodonts and early
anapsid reptilians in the form of enlargement of the first teeth on the
maxilla, forming a sort of protocanines. This trait was subsequently lost in the
diapsid line, but developed further in the synapsids. Early synapsids could have two or even three enlarged "canines", but in the therapsids, the pattern had settled to one canine in each upper jaw half. The lower canines developed later.
Jaw The jaw transition is a good
classification tool, as most other fossilized features that make a chronological progression from a reptile-like to a mammalian condition follow the progression of the jaw transition. The
mandible, or lower jaw, consists of a single, tooth-bearing bone in mammals (the dentary), whereas the lower jaw of modern and prehistoric reptiles consists of a conglomeration of smaller bones (including the dentary,
articular, and others). As they evolved in synapsids, these jaw bones were reduced in size and either lost or, in the case of the articular, gradually moved into the ear, forming one of the middle ear bones: while modern mammals possess the
malleus,
incus and
stapes,
basal synapsids (like all other tetrapods) possess only a stapes. The malleus is derived from the articular (a lower jaw bone), while the incus is derived from the
quadrate (a cranial bone). Mammalian jaw structures are also set apart by the dentary-squamosal
jaw joint. In this form of jaw joint, the dentary forms a connection with a depression in the
squamosal known as the
glenoid cavity. In contrast, all other jawed vertebrates, including reptiles and nonmammalian synapsids, possess a jaw joint in which one of the smaller bones of the lower jaw, the articular, makes a connection with a bone of the
cranium called the
quadrate bone to form the articular-quadrate jaw joint. In forms transitional to mammals, the jaw joint is composed of a large, lower jaw bone (similar to the dentary found in mammals) that does not connect to the squamosal, but connects to the quadrate with a receding articular bone.
Palate Synapsids ancestrally possess
palatal teeth present on the bones of the roof of the mouth. These were lost in the cynodont ancestors of mammals. Over time, as synapsids became more mammalian and less 'reptilian', they began to develop a
secondary palate, separating the mouth and
nasal cavity. In early synapsids, a secondary palate began to form on the sides of the
maxilla, still leaving the mouth and nostril connected. Eventually, the two sides of the palate began to curve together, forming a U shape instead of a C shape. The palate also began to extend back toward the throat, securing the entire mouth and creating a full
palatine bone. The maxilla is also closed completely. In fossils of one of the first
eutheriodonts, the beginnings of a palate are clearly visible. The later
Thrinaxodon has a full and completely closed palate, forming a clear progression.
Skin and fur has the densest fur of modern mammals. In addition to the glandular skin covered in fur found in most modern mammals, modern and extinct synapsids possess a variety of modified skin coverings, including
osteoderms (bony armor embedded in the skin),
scutes (protective structures of the dermis often with a horny covering), hair or fur, and
scale-like structures (often formed from modified hair, as in
pangolins and some
rodents). While the skin of reptiles is rather thin, that of mammals has a thick
dermal layer. Although the nature of early synapsid skin was previously subject of ambiguity, it has now been conclusively shown that early "pelycosaur" synapsids were covered in
epidermal scales similar to those of reptiles (with the bodies of at least some sphenacodontids having rectangular scales on the underside of the body while their limbs were covered in hexagonal scales). It has been suggested that epidermal scales evolved in their common ancestor prior to the split between reptiles and synapsids. It is currently unknown exactly when mammalian characteristics such as
body hair and
mammary glands first appeared, as the fossils only rarely provide direct evidence for soft tissues. The only unambiguous skin impressions known from non-cynodont therapsids are those of the dinocephalian
Estemmenosuchus from the Middle Permian of Russia and the dicynodont
Lystrosaurus from the Early Triassic of South Africa, which both exhibit "bulging ellipsoid
tubercules with a tendency to partially protrude one another, producing an overall pustular surface texture". Hair-like structures in
Late Permian coprolites from Russia and possibly South Africa may suggest that some therapsids had possibly acquired hair by this time, though the nature of these structures is ambiguous. The oldest known fossil showing unambiguous imprints of hair is the
Callovian (late middle
Jurassic)
Castorocauda and several contemporary
haramiyidans, both non-mammalian
mammaliaform (see below, however). More primitive members of the
Cynodontia are also hypothesized to have had fur or a fur-like covering based on their inferred warm-blooded metabolism. Mutation of the MSX2 gene in mice shows that when the gene is made non-functional, the mice fail to develop a hair coat, and the pineal foramen, which is ancestrally closed in mammals, becomes open. This may suggest that the two developments occurred around the same time in the cynodont ancestors of mammals.
Patagia Aerial locomotion first began in non-mammalian
haramiyidan cynodonts, with
Arboroharamiya,
Xianshou,
Maiopatagium and
Vilevolodon bearing exquisitely preserved, fur-covered wing membranes that stretch across the limbs and tail. Their fingers are elongated, similar to those of bats and
colugos and likely sharing similar roles both as wing supports and to hang on tree branches. Within true mammals, aerial locomotion first occurs in
volaticotherian
eutriconodonts. A fossil
Volaticotherium has an exquisitely preserved furry
patagium with delicate wrinkles and that is very extensive, "sandwiching" the poorly preserved hands and feet and extending to the base of the tail.
Argentoconodon, a close relative, shares a similar femur adapted for flight stresses, indicating a similar lifestyle.
Therian mammals would only achieve powered flight and gliding long after these early aeronauts became extinct, with the earliest-known gliding
metatherians and
bats evolving in the
Paleocene.
Reproduction and mammary glands therapsid
Lystrosaurus from the Early Triassic of South Africa, with life restoration showing embryo curled up in inferred (but unpreserved) egg Most or all non-mammalian synapsids may have laid relatively soft leathery eggs similar to those of
monotremes, which lack a relatively thick hard calcified shell like those found in many modern reptile and bird eggs. Egg laying in non-mammalian synapsids has seemingly been confirmed by a tightly coiled embryo of the
dicynodont therapsid
Lystrosaurus found in the Early Triassic of South Africa which was likely laid in an (unpreserved) soft leathery egg. Because they were vulnerable to
desiccation, secretions from
apocrine-like glands may have helped keep the eggs moist.), though this would limit the mobility of the parent. The latter may have been the primitive form of egg care in synapsids rather than simply burying the eggs, and the constraint on the parent's mobility would have been solved by having the eggs "parked" in nests during foraging or other activities and periodically be hydrated, allowing higher clutch sizes than could fit inside a pouch (or pouches) at once, and large eggs, which would be cumbersome to carry in a pouch, would be easier to care for. The basis of Oftedal's speculation is the fact that many species of
anurans can carry eggs or tadpoles attached to the skin, or embedded within cutaneous "pouches" and how most
salamanders curl around their eggs to keep them moist, both groups also having glandular skin.
Metabolism It has been disputed when
endothermy arose in the synapsid lineage. Some propose that it arose in the common ancestor of synapsids, others that endothermy is only present in members of Therapsida (perhaps with separate origins in dicynodonts and cynodonts), and that synapsids are ancestrally
ectothermic like reptiles. == Evolutionary history ==