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| Female Eastern Grey Kangaroo with a joey in her pouch|
It was once commonly believed that marsupials were a primitive forerunner of modern placental mammals, but fossil evidence, first presented by researcher M.J. Spechtt in 1982, conflicts with this assumption[How to reference and link to summary or text]. Instead, both main branches of the mammal tree appear to have evolved concurrently toward the end of the Mesozoic era. In the absence of soft tissues, such as the pouch and reproductive system, fossil marsupials can be distinguished from placentals by the form of their teeth; primitive marsupials possess four pairs of molar teeth in each jaw, whereas placental mammals never have more than three pairs.
Using this criterion, the earliest known marsupial is Sinodelphys szalayi, which lived in China around 125 million years ago. This makes it almost contemporary to the earliest placental fossils, which have been found in the same area.
Some scientists believe that the marsupials evolved in North America and dispersed from there, via Europe, to [Asia and [Africa. This diaspora would have also reached South America before it became an island continent. This theory suggests that marsupials passed from South America through Antarctica to Australia (via Gondwanan land connections), a continent already occupied by placental mammals. Alternatively, another theory posits that marsupials originated in Australia and traveled, via Antarctica and South America, to North America.
The discovery of Chinese marsupials appears to support the idea that marsupials reached Australia via Southeast Asia. However, marsupial fossils found in New Guinea are younger than those in Australia, evidence which presents a problem for this theory. There are a few species of marsupials still living in Asia, especially in the Sulawesi region of Indonesia. These marsupials coexist with primates, hooved mammals and other placentals.[How to reference and link to summary or text]
On most continents, placental mammals were much more successful and no marsupials survived, though in South America the opossums retained a strong presence, and the Tertiary saw the genesis of marsupial predators such as the borhyaenids and the saber-toothed Thylacosmilus. In Australia, however, marsupials displaced placental mammals entirely, and have since dominated the Australian ecosystem. Marsupial success over placental mammals in Australia has been attributed to their comparatively low metabolic rate, a trait which would prove helpful in the hot Australian climate.[How to reference and link to summary or text] As a result, native Australian placental mammals (such as hopping mice) are more recent immigrants.
An early birth removes a developing marsupial from its parent's body much sooner than in placental mammals, and thus marsupials have not developed a complex placenta to protect the embryo from its mother's immune system. Though early birth places the tiny newborn marsupial at a greater environmental risk, it significantly reduces the dangers associated with long pregnancies, as there is no need to carry a large fetus to full-term in bad seasons.
Because newborn marsupials must climb up to their mother's nipples, their front limbs are much more developed than the rest of the body at the time of birth. It is possible that this requirement has resulted in the limited range of locomotor adaptations in marsupials compared to placentals. Marsupials must develop a grasping forepaw during their early youth, making the transition from this limb into a hoof, wing, or flipper, as some groups of placental mammals have done, far more difficult.
There are about 334 species of marsupial, and over 200 are native to Australia and neighboring northern islands. There are also 100 extant American species; these are centered mostly in South America, but the Great American Interchange has provided Central America with 13 species, and North America with one (the Virginia Opossum).
A feature of marsupials (and also monotremes) is the claim they don't have a gross communication (corpus callosum) between the right and left brain hemisphere.[How to reference and link to summary or text]
Marsupials' reproductive systems differ markedly from those of their placental mammal cousins (Placentalia). Females have two vaginas, both of which open externally through one orifice but lead to different compartments within the uterus. Males generally have a two-pronged penis, which corresponds to the females' two vaginae. The penis is used only for discharging semen into females, and is separate from the urinary tract.[How to reference and link to summary or text] Both sexes possess a cloaca, which is connected to a urogenital sac used to store waste before expulsion.
Pregnant females develop a kind of yolk sac in their wombs, which delivers nutrients to the embryo. Marsupials give birth at a very early stage of development (about 4–5 weeks); after birth, newborn marsupials crawl up the bodies of their mothers and attach themselves to a nipple, which is located inside the marsupium. There they remain for a number of weeks, attached to the nipple. The offspring are eventually able to leave the marsupium for short periods, returning to it for warmth and nourishment.
Taxonomically, there are two primary divisions of Marsupialia: American marsupials and the Australian marsupials. The Order Microbiotheria (which has only one species, the Monito del Monte) is found in South America but is believed to be more closely related to the Australian marsupials. There are many small arboreal species in each group. The term opossums is properly used to refer to the American species (though possum is a common diminutive), while similar Australian species are properly called possums.
- Superorder Ameridelphia
- Superorder Australidelphia
- Order †Yalkaparidontia
- Order Microbiotheria (1 species)
- Order Dasyuromorphia (71 species)
- Order Peramelemorphia (24 species)
- Order Notoryctemorphia (2 species)
- Family Notoryctidae: marsupial moles
- Order Diprotodontia (137 species)
- Family Phascolarctidae: Koala
- Family Vombatidae: wombats
- Family †Diprotodontidae: diprotodon
- Family Phalangeridae: brushtail possums and cuscuses
- Family Burramyidae: pygmy possums
- Family Tarsipedidae: Honey Possum
- Family Petauridae: Striped Possum, Leadbeater's Possum, Yellow-bellied Glider, Sugar Glider, Mahogany Glider, Squirrel Glider
- Family Pseudocheiridae: ringtailed possums and relatives
- Family Potoridae: potoroos, rat kangaroos, bettongs
- Family Acrobatidae: Feathertail Glider and Feather-tailed Possum
- Family Hypsiprymnodontidae: Musky Rat-kangaroo
- Family Macropodidae: kangaroos, wallabies, and relatives
- Family †Thylacoleonidae: marsupial lions
- Order †Sparassodonta
† indicates extinction
- ↑ 1.0 1.1 Template:MSW3 Gardner
- ↑ 2.0 2.1 Groves, Colin (16 November 2005). Wilson, D. E., and Reeder, D. M. (eds) Mammal Species of the World, 3rd edition, 22–70, Johns Hopkins University Press. ISBN 0-801-88221-4.
- ↑ Benton, Michael J. (1997). Vertebrate Palaeontology, London: Chapman & Hall.
- ↑ 4.0 4.1  Iowa State University Biology Dept. Discoveries about Marsupial Reproduction Anna King 2001. webpage] (note shows code, html extension omitted)
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- The Marsupial Ring
- Western Australian Mammal Species
- Researchers Publish First Marsupial Genome Sequence The National Institutes of Health May 2007
- First marsupial genome released. Most differences between the opossom and placental mammals stem from non-coding DNA
Extant mammal orders by infraclass
Afrosoricida · Macroscelidea · Tubulidentata · Hyracoidea · Proboscidea · Sirenia · Cingulata · Pilosa · Scandentia · Dermoptera · Primates · Rodentia · Lagomorpha · Erinaceomorpha · Soricomorpha · Chiroptera · Pholidota · Carnivora · Perissodactyla · Artiodactyla · Cetacea