[Paleontology • 2024] Jurassic Fossil Juvenile reveals prolonged Life History in early Mammals

in Panciroli, Benson, Fernandez, Fraser, Humpage, Luo, Newham et Walsh, 2024.

DOI: 10.1038/s41586-024-07733-1 

 x.com/gsciencelady

Abstract

Living mammal groups exhibit rapid juvenile growth with a cessation of growth in adulthood. Understanding the emergence of this pattern in the earliest mammaliaforms (mammals and their closest extinct relatives) is hindered by a paucity of fossils representing juvenile individuals. We report exceptionally complete juvenile and adult specimens of the Middle Jurassic docodontan Krusatodon, providing anatomical data and insights into the life history of early diverging mammaliaforms. We used synchrotron X-ray micro-computed tomography imaging of cementum growth increments in the teeth to provide evidence of pace of life in a Mesozoic mammaliaform. The adult was about 7 years and the juvenile 7 to 24 months of age at death and in the process of replacing its deciduous dentition with its final, adult generation. When analysed against a dataset of life history parameters for extant mammals5, the relative sequence of adult tooth eruption was already established in Krusatodon and in the range observed in extant mammals but this development was prolonged, taking place during a longer period as part of a significantly longer maximum lifespan than extant mammals of comparable adult body mass (156 g or less). Our findings suggest that early diverging mammaliaforms did not experience the same life histories as extant small-bodied mammals and the fundamental shift to faster growth over a shorter lifespan may not have taken place in mammaliaforms until during or after the Middle Jurassic.

Krusatodon 

 

Elsa Panciroli, Roger B. J. Benson, Vincent Fernandez, Nicholas C. Fraser, Matt Humpage, Zhe-Xi Luo, Elis Newham and Stig Walsh. 2024. Jurassic Fossil Juvenile reveals prolonged Life History in early Mammals. Nature. DOI: doi.org/10.1038/s41586-024-07733-1

  x.com/gsciencelady/status/1816127777407385636

[PaleoMammalogy • 2021] Mammaliaform Extinctions as A Driver of the Morphological Radiation of Cenozoic Mammals

 large Gobiconodon outcompeted the ancestors of modern mammals in the time of dinosaurs.

in Brocklehurst, Panciroli, Benevento & Benson, 2021. 

 DOI: 10.1016/j.cub.2021.04.044

 twitter.com/palaeo_neil 

Illustration: Corbin Rainbolt.  twitter.com/CorbinRainbolt

Highlights

• The therian mammal radiation is usually associated with extinctions among dinosaurs

• Mesozoic therians show greater morphological constraint than their close relatives

• The release of this constraint occurred later than the extinction of the dinosaurs

• The therian radiation was in part driven by extinctions among other mammaliaforms

Summary

Adaptive radiations are hypothesized as a generating mechanism for much of the morphological diversity of extant species. The Cenozoic radiation of placental mammals, the foundational example of this concept, gave rise to much of the morphological disparity of extant mammals, and is generally attributed to relaxed evolutionary constraints following the extinction of non-avian dinosaurs. However, study of this and other radiations has focused on variation in evolutionary rates, leaving the extent to which relaxation of constraints enabled the origin of novel phenotypes less well characterized. We evaluate constraints on morphological evolution among mammaliaforms (mammals and their closest relatives) using a new method that quantifies the capacity of evolutionary change to generate phenotypic novelty. We find that Mesozoic crown-group therians, which include the ancestors of placental mammals, were significantly more constrained than other mammaliaforms. Relaxation of these constraints occurred in the mid-Paleocene, post-dating the extinction of non-avian dinosaurs at the K/Pg boundary, instead coinciding with important environmental shifts and with declining ecomorphological diversity in non-theriimorph mammaliaforms. This relaxation occurred even in small-bodied Cenozoic mammals weighing <100 g, which are unlikely to have competed with dinosaurs. Instead, our findings support a more complex model whereby Mesozoic crown therian evolution was in part constrained by co-occurrence with disparate mammaliaforms, as well as by the presence of dinosaurs, within-lineage incumbency effects, and environmental factors. Our results demonstrate that variation in evolutionary constraints can occur independently of variation in evolutionary rate, and that both make important contributions to the understanding of adaptive radiations.

Keywords: adaptive radiation, constraint, mammal, Mesozoic, K/Pg mass extinction

Early lineages of mammal like this large Gobiconodon from Mongolia outcompeted the ancestors of modern mammals in the time of dinosaurs.

Illustration: Corbin Rainbolt.

 twitter.com/CorbinRainbolt

 

Neil Brocklehurst, Elsa Panciroli, Gemma Louise Benevento and Roger B.J. Benson. 2021. Mammaliaform Extinctions as A Driver of the Morphological Radiation of Cenozoic Mammals. Current Biology. DOI: 10.1016/j.cub.2021.04.044

 twitter.com/palaeo_neil/status/1394303018565255172

In brief: Brocklehurst et al. report that Mesozoic therians evolved under greater morphological constraint than contemporary mammaliaforms. This constraint was released later than the extinction of non-avian dinosaurs, including in therians less than 100 g. They suggest the therian radiation was in part driven by extinctions among non-therian mammaliaforms.

Mammals in the time of dinosaurs held each other back

  eurekalert.org/pub_releases/2021-05/uoo-mit051721.php

 twitter.com/CorbinRainbolt/status/1394313394178727940

[Paleontology • 2019] The Postcranial Anatomy of Brasilodon quadrangularis and the Acquisition of Mammaliaform Traits Among Non-mammaliaform Cynodonts

Brasilodon quadrangularis 

Bonaparte, Martinelli, Schultz & Rubert, 2003

 from the Riograndia Assemblage Zone of the Candelária Sequence, Santa Maria Supersequence (Brazil).

  Illustration: Jorge Blanco. 

in Guignard, Martinelli & Soares, 2019. 

 DOI: 10.1371/journal.pone.0216672

Abstract

Brasilodon quadrangularis (Cynodontia, Probainognathia) is an iconic non-mammaliaform cynodont from the Late Triassic of Brazil (Riograndia Assemblage Zone, Candelária Sequence), being considered as the sister taxon of Mammaliaformes. Although its phylogenetic position is very important, several aspects of its postcranial anatomy remain unclear or unstudied. Here, we present a detailed description of the postcranial elements referred to Brasilodon, including previously mentioned specimens and new ones, which add relevant information about its postcranial morphology and provide a new insight into the anatomical transition between advanced non-mammaliaform cynodonts and early mammaliaforms. Functional and ecological implications are also investigated, based on the postcranial morphology and muscular reconstructions. The postcranium of Brasilodon differs from most non-mammaliaform cynodonts and presents similarities with tritylodontids, early mammaliaforms and extant therians, such as a ventrally oriented scapular glenoid facet, a distinct and ossified greater humeral tubercle, lack of ectepicondylar foramen, olecranon process, hemispherical humeral and femoral heads and a prominent intertrochanteric crest. The humeral torsion, the length of the deltopectoral crest, the large bicipital groove and the well-developed lesser tubercle, indicate that the forelimb of Brasilodon was hold in a semi-sprawling position, with well-developed adductor muscles to maintain the body off the ground. The short femoral neck and the strong medial projection of the femoral head indicate the femur was held in a more erect posture than in basal non-mammaliaform cynodonts. The anterodorsally projected iliac blade with reduced postacetabular process, reduction of the anterior part of the pubis, medially located lesser trochanter indicate a basically mammalian pattern of pelvic musculature, able to swing the femur in a nearly parasagittal plane.

Fig 13. Paleoartistic reconstruction of Brasilodon quadrangularis (left) and Riograndia guaibensis (right), two abundant probainognathian cynodonts from the Riograndia Assemblage Zone of the Candelária Sequence, Santa Maria Supersequence (Brazil), which exhibits different morphologies in skull, dentition and locomotor apparatus.

 Illustration: Jorge Blanco.

Conclusion: 

The postcranium of Brasilodon quadrangularis differs from other non-mammaliaform cynodonts and is similar to early mammaliaforms and extant therians (e.g., hemispherical humeral and femoral head, distinct greater tubercle of the humerus, circular acetabulum, salient intertrochanteric crest of the femur). The morphology of the ulnar condyle of the humerus and olecranon process of the ulna suggests more abilities for extension and flexion of the elbow, a necessary component for a parasagittal locomotion. However, the humeral torsion, the length of the deltopectoral crest, the large bicipital groove and the well-developed lesser tubercle, indicate that the forelimb of B. quadrangularis was hold in a semi-sprawling position, with well-developed adductor muscles to maintain the body off the ground. The short femoral neck and the strong medial projection of the femoral head indicate the femur was held in a more erect posture than in basal non-mammaliaform cynodonts. The anterodorsally projected iliac blade with reduced postacetabular process, enlarged obturator foramen, reduction of the anterior part of the pubis, prominent and distinctive greater trochanter, medially located lesser trochanter, narrow intertrochanteric fossa represent a further continuation of trends that indicates a basically mammalian pattern of pelvic musculature, able to swing the femur in a nearly parasagittal plane.

Although fossorial or semifossorial habits appear to have been common in derived non-mammaliaform probainognathians (i.e., Riograndia, Irajatherium and Kayentatherium), the postcranial study of B. quadrangularis shows more generalized adaptations and highlights that distinctive ecological strategies (Fig 13) were developed among small-sized non-mammaliaform cynodonts.

 Morgan L. Guignard, Agustin G. Martinelli and Marina B. Soares. 2019. The Postcranial Anatomy of Brasilodon quadrangularis and the Acquisition of Mammaliaform Traits Among Non-mammaliaform Cynodonts.  PLoS ONE. 14(5): e0216672. DOI: 10.1371/journal.pone.0216672

[PaleoMammalogy • 2018] Cifelliodon wahkarmoosuch • Late-surviving Stem Mammal Links the Lowermost Cretaceous of North America and Gondwana

 Cifelliodon wahkarmoosuch 

Huttenlocker, Grossnickle, Kirkland, Schultz  & Luo, 2018

  DOI:  10.1038/s41586-018-0126-y

 Illustration: Jorge A. Gonzalez  nature.com

Abstract

Haramiyida was a successful clade of mammaliaforms, spanning the Late Triassic period to at least the Late Jurassic period, but their fossils are scant outside Eurasia and Cretaceous records are controversial. Here we report, to our knowledge, the first cranium of a large haramiyidan from the basal Cretaceous of North America. This cranium possesses an amalgam of stem mammaliaform plesiomorphies and crown mammalian apomorphies. Moreover, it shows dental traits that are diagnostic of isolated teeth of supposed multituberculate affinities from the Cretaceous of Morocco, which have been assigned to the enigmatic ‘Hahnodontidae’. Exceptional preservation of this specimen also provides insights into the evolution of the ancestral mammalian brain. We demonstrate the haramiyidan affinities of Gondwanan hahnodontid teeth, removing them from multituberculates, and suggest that hahnodontid mammaliaforms had a much wider, possibly Pangaean distribution during the Jurassic–Cretaceous transition.

The new species Cifelliodon wahkarmoosuch is estimated to have weighed 2.5 pounds and probably grew to be about the size of a small hare.

 Illustration: Jorge A. Gonzalez

Mammaliaformes sensu Rowe (1986) 

Haramiyida Hahn, Sigogneau-Russell and Wouters (1989) 

Hahnodontidae Sigogneau-Russell (1991) 

Cifelliodon gen. nov.

Cifelliodon wahkarmoosuch sp. nov.  

Etymology. Cifelli’s tooth (Latin: -odon) of the Yellow Cat (Ute language: yellow, wahkar; cat, moosuch). Genus name honours Richard Cifelli for his contributions to Cretaceous mammal research in the American West.

Holotype. An exceptionally preserved skull, UMNH VP 16771 (Natural History Museum of Utah, Vertebrate Paleontology Collection).

Locality and horizon. The holotype is from the ‘Andrew’s Site’ quarry in the Lower Cretaceous Yellow Cat Member, Cedar Mountain Formation, Grand County, Utah, USA15. Radiometric dating places the age between approximately 139 and 124 million years old.

Diagnosis. Medium-to-large Mesozoic mammaliaform with broad, shallow skull and rostrum and a reduced marginal tooth count; dental formula: I2:C1:PC4; ultimate upper molars with high anterobuccal cusp and low, broad posterolingual cusp connected by a low ridge; septomaxilla absent; incisive foramina enlarged and positioned posteriorly on palate behind the level of the last (posterior) incisor pair; massive pterygoid transverse process that extends far ventral to the palatal surface; attenuated lacrimal anterior process with limited nasolacrimal contact; prominent sagittal crest; extensive occipital exposure of parietal and postparietal; plesiomorphic retention of a tabular bone; differs from Hahnodon in its larger size and higher aspect ratio of the rear molar in occlusal view (slightly more triangular than oval, with posterior apex).

The new species Cifelliodon wahkarmoosuch is estimated to have weighed 2.5 pounds and probably grew to be about the size of a small hare.

 Illustration: Jorge A. Gonzalez 

Adam K. Huttenlocker, David M. Grossnickle, James I. Kirkland, Julia A. Schultz and Zhe-Xi Luo. 2018. Late-surviving Stem Mammal Links the Lowermost Cretaceous of North America and Gondwana. Nature.  DOI:  10.1038/s41586-018-0126-y

A 3D view of early mammals   nature.com/articles/d41586-018-05134-9

 twitter.com/Paleojim/status/999410808424574976

[PaleoMammalogy • 2017] Maiopatagium furculiferum • A New Gliding Mammaliaforms from the Jurassic of China

Maiopatagium furculiferum 

Meng, Grossnickle, Liu, Zhang, Neander, Ji & Luo, 2017 

Reconstruction by April I. Neander | DOI: 10.1038/nature23476 

Stem mammaliaforms are Mesozoic forerunners to mammals, and they offer critical evidence for the anatomical evolution and ecological diversification during the earliest mammalian history. Two new eleutherodonts from the Late Jurassic period have skin membranes and skeletal features that are adapted for gliding. Characteristics of their digits provide evidence of roosting behaviour, as in dermopterans and bats, and their feet have a calcaneal calcar to support the uropagatium as in bats. The new volant taxa are phylogenetically nested with arboreal eleutherodonts. Together, they show an evolutionary experimentation similar to the iterative evolutions of gliders within arboreal groups of marsupial and placental mammals. However, gliding eleutherodonts possess rigid interclavicle–clavicle structures, convergent to the avian furculum, and they retain shoulder girdle plesiomorphies of mammaliaforms and monotremes. Forelimb mobility required by gliding occurs at the acromion–clavicle and glenohumeral joints, is different from and convergent to the shoulder mobility at the pivotal clavicle–sternal joint in marsupial and placental gliders.

Clade Mammaliaformes

Clade Haramiyida 

Clade (Order) Eleutherodontida

Maiopatagium furculiferum gen. et sp. nov.

Etymology: Maio (Latin): mother; patagium (Latin): skin membrane, referring to the preserved patagial membranes of the fossil; furcula (Latin): fork; ferum (Latin): similar, in reference to the sutured and/or fused interclavicle and clavicles that are morphologically convergent to the furculum (wishbone) of birds.

Locality and geologic age: The Daxishan fossil site of Linglongta township, Jianchang County, Liaoning Province, China. The fossil slab has preserved specimens of the index fossil Qaidamestheria sp. (Euestheria luanpingensis) that are known from the upper fossiliferous stratigraphic level of the Tiaojishan Formation. The vertebrate-bearing level of this site is dated to be 158.5 ± 1.6 to 161.0 ± 1.44 million years old. The Tiaojishan fauna has yielded several additional mammaliaforms.

fossil of gliding mammaliaform Maiopatagium furculiferum (type specimen from Beijing Museum of Natural History BMNH 2940).

photo: Zhe-Xi Luo 

Maiopatagium in Jurassic forest in crepuscular (dawn and dusk) light: A mother with a baby in suspending roosting posture, climbing on tree trunk, and in gliding

 Reconstruction by April I. Neander 

Qing-Jin Meng, David M. Grossnickle, Di Liu, Yu-Guang Zhang, April I. Neander, Qiang Ji & Zhe-Xi Luo. 2017. New Gliding Mammaliaforms from the Jurassic. Nature. DOI: 10.1038/nature23476

Researchers discover first winged mammals from the Jurassic period  phy.so/421491290 via @physorg_com

Rare Fossils Reveal New Species of Ancient Gliding Mammals  on.NatGeo.com/2vmGyCJ via @NatGeo

  

[PaleoMammalogy • 2015] Agilodocodon scansorius & Docofossor brachydactylus • Earliest-known Arboreal and Subterranean Ancestral Mammals from Middle Jurassic of China

Early mammals had a surprisingly wide range of adaptations, ranging from the tree-climbing Agilodocodon (top) to the swimming Castorocauda (in the water) and the burrowing Docofossor (bottom).

Illustration: April I. Neander | ScienceMag.org 

fossils of Docofossor (left) and Agilodocodon (right), the earliest-known subterranean and arboreal mammals.

What were the lives of the earliest mammals like? For many, what comes to mind is an image of a small, insect-eating creature that scurried about at night, hiding from dinosaurs and eking out a meager existence. After all, intense competition from the terrible lizards must surely have forced our very distant ancestors into very limited ecological niches.

While there’s some truth to this stereotype, more and more evidence suggests that early mammals were actually remarkably diverse. The fossils of two interrelated ancestral mammals, newly discovered in China, now help confirm that the wide-ranging ecological diversity of modern mammals had a precedent more than 160 million years ago.

With claws for climbing and teeth adapted for a tree sap diet, Agilodocodon scansorius is the earliest-known tree-dwelling mammaliaform (long-extinct relatives of modern mammals). The other fossil, Docofossor brachydactylus, is the earliest-known subterranean mammaliaform, possessing multiple adaptations similar to African golden moles such as shovel-like paws. Docofossor also has distinct skeletal features that resemble patterns shaped by genes identified in living mammals, suggesting these genetic mechanisms operated long before the rise of modern mammals.

These discoveries are reported by international teams of scientists from the University of Chicago and Beijing Museum of Natural History in two separate papers published Feb. 13 in Science.

“We consistently find with every new fossil that the earliest mammals were just as diverse in both feeding and locomotor adaptations as modern mammals,” said Zhe-Xi Luo, PhD, professor of organismal biology and anatomy at the University of Chicago and senior author on both papers. “The groundwork for mammalian success today appears to have been laid long ago.”

......

Earliest-known Arboreal and Subterranean Ancestral Mammals Discovered

http://sciencelife.uchospitals.edu/2015/02/12/earliest-known-arboreal-and-subterranean-ancestral-mammals-discovered/

Stem mammaliaforms (also known as “stem mammals”) are long-extinct relatives to the extant mammals (crown Mammalia). Docodonts are such a lineage of stem mammaliaforms. Their morphologies provide evidence for the ancestral mammalian condition.

ScienceLife.UCHospitals.edu

A new docodontan mammaliaform from the Middle Jurassic of China has skeletal features for climbing and dental characters indicative of an omnivorous diet that included plant sap. This fossil expands the range of known locomotor adaptations in docodontans to include climbing, in addition to digging and swimming. It further shows that some docodontans had a diet with a substantial herbivorous component, distinctive from the faunivorous diets previously reported in other members of this clade. This reveals a greater ecological diversity in an early mammaliaform clade at a more fundamental taxonomic level not only between major clades as previously thought.

Qing-Jin Meng, Qiang Ji, Yu-Guang Zhang, Di Liu, David M. Grossnickle and Zhe-Xi Luo. 2015. An Arboreal Docodont from the Jurassic and Mammaliaform Ecological Diversification. Science. 347(6223); 764-768; doi: 10.1126/science.1260879

A new Late Jurassic docodontan shows specializations for a subterranean lifestyle. It is similar to extant subterranean golden moles in having reduced digit segments as compared to the ancestral phalangeal pattern of mammaliaforms and extant mammals. The reduction of digit segments can occur in mammals by fusion of the proximal and intermediate phalangeal precursors, a developmental process for which a gene and signaling network have been characterized in mouse and human. Docodontans show a positional shift of thoracolumbar ribs, a developmental variation that is controlled by Hox9 and Myf5 genes in extant mammals. We argue that these morphogenetic mechanisms of modern mammals were operating before the rise of modern mammals, driving the morphological disparity in the earliest mammaliaform diversification.

Zhe-Xi Luo, Qing-Jin Meng, Qiang Ji, Di Liu, Yu-Guang Zhang and April I. Neander. 2015. Evolutionary Development in Basal Mammaliaforms as revealed by A Docodontan. Science. 347(6223); 760-764; doi: 10.1126/science.1260880

  

Found: Two sophisticated mammals that thrived during the age of the dinosaurs http://news.sciencemag.org/evolution/2015/02/found-two-sophisticated-mammals-thrived-during-age-dinosaurs

2 Jurassic Mini Mammal Species Discovered in China http://shar.es/1oLGia via @LiveScience

Meet the furry Jurassic period critters that outwitted the dinosaurs http://wapo.st/1KSD36z

[PaleoMammalogy • 2013] Megaconus mammaliaformis • A Jurassic mammaliaform and the earliest mammalian evolutionary adaptations

A fossil of the forest-floor-dwelling animal Megaconus suggests that its group predated mammals — whereas a fossil of its tree-dwelling cousin Arboroharamiya (see picture below) seems to show that the group belonged in the mammalian family tree.

The earliest evolution of mammals and origins of mammalian features can be traced to the mammaliaforms of the Triassic and Jurassic periods that are extinct relatives to living mammals. Here we describe a new fossil from the Middle Jurassic that has a mandibular middle ear, a gradational transition of thoracolumbar vertebrae and primitive ankle features, but highly derived molars with a high crown and multiple roots that are partially fused. The upper molars have longitudinal cusp rows that occlude alternately with those of the lower molars. This specialization for masticating plants indicates that herbivory evolved among mammaliaforms, before the rise of crown mammals. The new species shares the distinctive dental features of the eleutherodontid clade, previously represented only by isolated teeth despite its extensive geographic distribution during the Jurassic. This eleutherodontid was terrestrial and had ambulatory gaits, analogous to extant terrestrial mammals such as armadillos or rock hyrax. Its fur corroborates that mammalian integument had originated well before the common ancestor of living mammals.

tree-dwelling cousin Arboroharamiya 

Zhou, C. F.; Wu, S.; Martin, T.; Luo, Z. X. 2013. A Jurassic mammaliaform and the earliest mammalian evolutionary adaptations. Nature. 500(7461): 163. 

doi: dx.doi.org/10.1038/nature12429 10.1038/nature.2013.13522

http://derstandard.at/1375625979925/Ueberraschende-Fossilienfunde-bringen-Verwirrung-in-den-Saeugetier-Stammbaum