Suborder of reptiles
The
Cryptodira
(
Greek
:
hidden neck
) are a
suborder
of
Testudines
that includes most living
tortoises
and
turtles
. Cryptodira differ from
Pleurodira
(side-necked turtles) in that they lower their necks and pull the heads straight back into the shells, instead of folding their necks sideways along the body under the shells' marginals. They include among their species
freshwater turtles
,
snapping turtles
,
tortoises
,
softshell turtles
, and
sea turtles
.
Neck retraction
[
edit
]
The Cryptodira are characterized by retraction of the head in the vertical plane, which permits for primarily vertical movements and restricted lateral movements outside of the shell.
[3]
These motions are largely due to the morphology and arrangement of
cervical vertebrae
. In all recent turtles, the cervical column consists of nine joints and eight vertebrae.
[4]
Compared to the narrow vertebrae and the closely positioned
zygapophyses
of the pleurodires, the cryptodires’ vertebrae take on the opposite shape. Their cervical vertebrae are more distended, and their zygapophyses (processes that interlock adjacent vertebrae) are much more widely spaced?features allowing for a condition called
ginglymoidy
, and ultimately, their “hidden” neck retraction. Ginglymoidy refers to the double articulation where articulation between the sixth and seventh vertebrae and the seventh and eighth vertebrae allows for bending of the neck into an S shape. Formation of this S shape occurs in one plane that enables retraction into the shell.
[5]
Cryptodiran neck retraction is also dependent on associated cervical musculature for its characteristic motions. A study that focused solely on the mechanism of neck retraction in
Chelodina
(pleurodire) versus that of
Apalone
(cryptodire), found an absence of the
longissimus
and
iliocostalis
systems and reduced epaxial musculature.
[4]
Absence of longissimus musculature, which primarily functions in moving the neck via ipsilateral flexion and contralateral rotation, contributes to the backwards retraction of the neck into the shell. Lack of this muscular system also results in poorly developed
transverse processes
(the lateral processes of a vertebra), forcing them to be developed in a more cranial direction. The iliocostalis system, used for lateral flexion and extension of the vertebral column, is commonly absent in all turtles. With the presence of a shell, these muscular movements are no longer possible. Epaxial musculature that functions in alternated forms of stepping and walking is minimized in turtles, due to their restricted stride lengths and heavily weighted shells.
[
citation needed
]
Systematics and evolution
[
edit
]
Cryptodires
evolved
from pleurodires during the early
Jurassic
period, originating from
South America
and
Southeast Asia
.
[6]
By the end of the Jurassic, cryptodires had almost completely replaced pleurodires in the lakes and rivers, while beginning to develop land-based species. Meanwhile, pleurodires became the dominant freshwater testudines in the
Cretaceous
to
Eocene
of
Europe
,
[7]
and produced a family of marine species, the
Bothremydidae
.
The Cryptodira suborder has four living
superfamilies
, the
Chelonioidea
(sea turtles),
Testudinoidea
(tortoises and pond turtles),
Kinosternoidea
(Central American river turtle and mud turtles) and
Trionychoidea
(soft-shell turtles and relatives).
Chelydridae
(snapping turtles) form a sister group to
Kinosternoidea
. The former three subfamilies (and Chelydridae) are classified in the clade
Durocryptodira
, while the latter is classified in the clade
Trionychia
. These two clades likely diverged in the middle of the Jurassic.
[6]
[8]
Two circumscriptions of the Cryptodira are commonly found. One is used here; it includes a number of primitive
extinct
lineages known only from
fossils
, as well as the Eucryptodira. These are, in turn, made up from some very
basal
groups, and the Centrocryptodira contain the prehistoric relatives of the living cryptodires, as well as the latter, which are collectively called Polycryptodira or Durocryptodira.
The alternate concept restricts the use of the term "Cryptodira" to the
crown clade
(i.e. Polycryptodira). The Cryptodira as understood here are called
Cryptodiramorpha
in this view.
A recent study placed
Plesiochelyidae
as an
Angolachelonia
and outside
Testudines
, thus Cryptodira.
[9]
As per the system used here, the Cryptodira can be classified as:
[8]
[10]
Distribution
[
edit
]
- Trionychidae (softshell turtles) are found from North America, Africa, South and East Asia to New Guinea.
- Kinosternidae (mud and musk turtles) are found from eastern North America to the Amazon drainage of South America.
- Dermatemydidae (Mesoamerican river turtles) are found in the Caribbean-Gulf drainage of Mesoamerica.
- Emydidae (cooters, sliders, American box turtles, and Allies) are found from Europe to Ural Mountains and North America southward to Eastern Brazil.
References
[
edit
]
- ^
a
b
Rhodin 2011
, p. 000.171
- ^
Rhodin 2008
, p. 000.3
- ^
Anquetin, Jeremy; Tong, Haiyan; Claude, Julien (16 February 2017).
"A Jurassic stem pleurodire sheds light on the functional origin of neck retraction in turtles"
.
Scientific Reports
.
7
(1): 42376.
Bibcode
:
2017NatSR...742376A
.
doi
:
10.1038/srep42376
.
PMC
5312562
.
PMID
28206991
.
- ^
a
b
Biology of turtles
. Wyneken, Jeanette, 1956-, Bels, V. L. (Vincent L.), Godfrey, Matthew H. Boca Raton: CRC Press. 2008.
ISBN
9780849333392
.
OCLC
144570900
.
{{
cite book
}}
: CS1 maint: others (
link
)
- ^
"ginglymoidy - oi"
. Archived from
the original
on 2020-01-31
. Retrieved
2018-05-05
.
- ^
a
b
Pereira, Anieli G.; Sterli, Juliana; Moreira, Filipe R.R.; Schrago, Carlos G. (August 2017).
"Multilocus phylogeny and statistical biogeography clarify the evolutionary history of major lineages of turtles"
.
Molecular Phylogenetics and Evolution
.
113
: 59?66.
doi
:
10.1016/j.ympev.2017.05.008
.
hdl
:
11336/41137
.
ISSN
1055-7903
.
PMID
28501611
.
- ^
Perez-Garcia, Adan (4 June 2016). "A new turtle confirms the presence of Bothremydidae (Pleurodira) in the Cenozoic of Europe and expands the biostratigraphic range of Foxemydina".
The Science of Nature
.
103
(7?8): 50.
Bibcode
:
2016SciNa.103...50P
.
doi
:
10.1007/s00114-016-1375-y
.
PMID
27262289
.
S2CID
15652309
.
- ^
a
b
Joyce, Walter G.; Anquetin, Jeremy; Cadena, Edwin-Alberto; Claude, Julien; Danilov, Igor G.; Evers, Serjoscha W.; Ferreira, Gabriel S.; Gentry, Andrew D.; Georgalis, Georgios L.; Lyson, Tyler R.; Perez-Garcia, Adan (2021-02-09).
"A nomenclature for fossil and living turtles using phylogenetically defined clade names"
.
Swiss Journal of Palaeontology
.
140
(1): 5.
doi
:
10.1186/s13358-020-00211-x
.
hdl
:
11336/155192
.
ISSN
1664-2384
.
- ^
Evers, Serjoscha W.; Benson, Roger B. J.; Smith, Andrew (January 2019).
"A new phylogenetic hypothesis of turtles with implications for the timing and number of evolutionary transitions to marine lifestyles in the group"
.
Palaeontology
.
62
(1): 93?134.
doi
:
10.1111/pala.12384
.
S2CID
134736808
.
- ^
Anquetin, Jeremy (9 November 2011).
"Reassessment of the phylogenetic interrelationships of basal turtles (Testudinata)"
.
Journal of Systematic Palaeontology
.
10
(1): 3?45.
doi
:
10.1080/14772019.2011.558928
.
S2CID
85295987
.
Further reading
[
edit
]
- Baur, George (June 1890).
"On the Classification of the Testudinata"
.
The American Naturalist
.
24
(282): 530?536.
doi
:
10.1086/275138
.
JSTOR
2450882
.
- Rhodin, Anders G.J.; van Dijk, Peter Paul; Inverson, John B.; Shaffer, H. Bradley; Roger, Bour (2011-12-31).
"Turtles of the world, 2011 update: Annotated checklist of taxonomy, synonymy, distribution and conservation status"
(PDF)
.
Chelonian Research Monographs
.
5
. Archived from
the original
(PDF)
on 2012-01-31.
- Rhodin, Anders G.J.; van Dijk, Peter Paul; Parham, James F. (2008-12-08).
"Turtles of the world, 2008 checklist"
(PDF)
.
Chelonian Research Monographs
.
5
. Archived from
the original
(PDF)
on 2012-04-23
. Retrieved
2012-05-22
.