The squirrel is in the detail: Anatomy and morphometry of the tail in Sciuromorpha (Rodentia, Mammalia)

In mammals, the caudal vertebrae are certainly among the least studied elements of their skeleton. However, the tail plays an important role in locomotion (e.g., balance, prehensility) and behavior (e.g., signaling). Previous studies largely focused on prehensile tails in Primates and Carnivora, in which certain osteological features were selected and used to define tail regions (proximal, transitional, distal). Interestingly, the distribution pattern of these anatomical characters and the relative proportions of the tail regions were similar in both orders. In order to test if such tail regionalization can be applied to Rodentia, we investigated the caudal vertebrae of 20 Sciuridae and six Gliridae species. Furthermore, we examined relationships between tail anatomy/morphometry and locomotion. The position of selected characters along the tail was recorded and their distribution was compared statistically using Spearman rank correlation. Vertebral body length (VBL) was measured to calculate the proportions of each tail region and to perform procrustes analysis on the shape of relative vertebral body length (rVBL) progressions. Our results show that tail regionalization, as defined for Primates and Carnivora, can be applied to almost all investigated squirrels, regardless of their locomotor category. Moreover, major locomotor categories can be distinguished by rVBL progression and tail region proportions. In particular, the small flying squirrels Glaucomys volans and Hylopetes sagitta show an extremely short transitional region. Likewise, several semifossorial taxa can be distinguished by their short distal region. Moreover, among flying squirrels, Petaurista petaurista shows differences with the small flying squirrels, mirroring previous observations on locomotory adaptations based on their inner ear morphometry. Our results show furthermore that the tail region proportions of P. petaurista, phylogenetically more basal than the small flying squirrels, are similar to those of bauplan-conservative arboreal squirrels.

Relationship between sacral shape variation and phylogeny in Old World monkeys

The sacrum, an essential skeletal element in the trunk, articulates with the ilium and lumbar and caudal vertebrae. While there are known morphological differences between hominoids and cercopithecoids (Old World monkeys), sacral morphological variations among cercopithecoids have rarely been studied outside of research on tail length variation. Increased knowledge regarding sacral variations in extant primates, however, could help in understanding and reconstructing their evolutionary development. Therefore, this study aimed to explore phylogenetic sacral shape variations among cercopithecoids. Geometric morphometric analyses were performed on 221 sacra from 39 different cercopithecoid species. Clear shape differences were observed among Colobinae, Cercopithecini, and Papionini, particularly in the spinous processes and sacral lateral mass. These parts function as muscle attachment points or skeletal joints, and variations in them seemed to reflect their required functions. However, the significance of the relationship between shape and function was not so great as to explain all the observed variation. According to recent genetic/developmental biological studies, shape variations may also be caused by the pleiotropic effects of some genes, such as posterior Hox genes. Therefore, while skeletal morphology has previously been considered to be directly connected to skeletal function, this study's results suggest that other factors influencing sacral shape require further research.

Classification of the "human tail": Correlation between position, associated anomalies, and causes

INTRODUCTION

Numerous case reports have indicated that the "human tail" is not always a harmless protrusion but can be associated with anomalies such as occult dysraphic malformations. However, the definition and classification of this anomaly have not been discussed. A prevailing hypothesis is that the "human tail" is a residual embryonic tail. Herein, we attempted to classify and define the human tail and investigate the frequency of this anomaly.

MATERIALS AND METHODS

We first defined the human tail as a protrusion on the dorsal side of the lumbar, sacrococcygeal, and para-anal regions identified after birth. We collected case reports written in English, Japanese, French, German, and Italian that were published from the 1880s to the present.

RESULTS

We discovered two important findings: (a) the cause of this anomaly may differ even though the "tails" resemble each other closely in appearance and (b) its position tends to be correlated with the type of anomaly and its associated cause. We propose a new classification of the human tail based on these findings.

CONCLUSION

Our classification may facilitate more accurate treatment and precise case descriptions of the human tail.