Vibrissal touch in the Etruscan shrew
| Claudia Roth-Alpermann and Michael Brecht (2009), Scholarpedia, 4(11):6830. | doi:10.4249/scholarpedia.6830 | revision #150470 [link to/cite this article] |
The Etruscan shrew Suncus etruscus (also known as white-toothed pygmy shrew) is the smallest terrestrial mammal with a body weight of 2 g and a body length of around 4 cm without tail (Fig.<ref>F1</ref>A). Shrews feed on insects and they use the sense of touch to detect and hunt prey. The elongated rostrum of the shrew has long whiskers referred to as macrovibrissae (Fig.<ref>F1</ref>A, B); the shrew’s mouth is surrounded by a dense array of short whiskers, the so-called microvibrissae (Fig.<ref>F1</ref>C).
Contents |
Behavioral ecology
<review> Add a sentence or two on the systematics of the shrew </review> Etruscan shrews can be found from the Mediterranean to southwest China in a belt extending between 10° and 30°N latitude <review> It would be nice to add a distribution map of this shrew </review>. Their habitat includes forest, shrub and grassland environments. Being hunted by predatory birds and owls, shrews try to avoid moving uncovered in the open field, but rather seek shelter under stones, leaves or in loose soil. They are specialized for a life in slits found in <review> (under?) </review> rocks or stones and are able to enter and successfully hunt in slits as thin as 7 millimeters. Etruscan shrews successfully hunt and feed on insects that have almost the same body size as themselves and crickets are amongst their preferred food.
The small body size of Etruscan shrews goes along with an extraordinarily high energy turnover. They feed up to 25 times a day and consume more than their own body weight in food. Heart, respiratory system and skeletal muscles are functionally and structurally adapted to meet the enormous metabolic needs (Jürgens, 2002). In case of food restriction and at low ambient temperature, Etruscan shrews can reduce their body temperature and enter a resting state called “torpor” to cut down their energy expenditure (Fons et al., 1997). Traditionally, shrews (including Suncus etruscus) have been regarded as nocturnal animals. However, probably due to their constant food requirement, they may actually have a polyphasic circadian activity pattern with frequent activity bouts distributed over a period of 24 hours. This means that shrews have to be able to successfully hunt in twilight as well as in darkness, i.e., under conditions where vision is of limited use and, indeed, sight only seems to play a minor role. Work on relative shrew species from the Crocidura genus implicated vibrissae in navigation, but argued against the presence of echolocation in these animals (Grünwald, 1969).
A synopsis of sensory ecology of Etruscan shrews suggests the following picture: They live and hunt in slits inaccessible to larger animals. Here they rely on touch rather than on long-distance sensory modalities such as vision. Thus, shrews can be regarded as short-range/high-speed animals.
Tactile prey capture behavior
Etruscan shrew prey capture is guided by tactile cues (Anjum and Brecht, 2006). In a laboratory setting, hunting was filmed in total darkness under infrared illumination while crickets were offered as prey. These experiments demonstrated that Etruscan shrews attack in a precise and fast manner and that they need their whiskers to hunt successfully.
Spatio-temporal analysis of attacks on crickets
Spatial attack characteristics. Etruscan shrews place their attacks selectively on the cricket’s thorax (Fig.<ref>F2</ref> A, B) and manage to keep this precision regardless of the size of the prey . They attack crickets from the side with a narrow distribution of attack angles around 90° relative to the cricket’s body axis. Although most attacks are directed straight ahead, some shrews show a lateralization with significantly more rightward attacks than leftward attacks <review> rightward and leftward in reference to what/where? </review>.
Temporal attack characteristics. Prey capture occurs very fast, in 80-200 ms per attack, with short inter-attack intervals <review> specify the range of durations </review> (Fig.<ref>F2</ref> C, D). <review> The following part is both spatial and temporal related and should be labeled as the "dynamics" of the attacks </review> While first attacks are distributed relatively broadly over the cricket’s body, subsequent attacks are directed more and more precisely to the thorax with the help of corrective head turns that the shrews perform. Thus, shrews can use contact information from a distant body part of the cricket to guide attacks towards their preferred location.
Whisker dependence and tactile shape recognition
Both macro- and microvibrissae are required for hunting, with the macrovibrissae being particularly relevant for attack targeting. Shrews attack a plastic replica of a cricket but not other objects of similar size. Altering the shape of crickets by gluing on additional body parts from donor animals reveals that the jumping legs but not the head are key features in prey recognition. Addition of such “ectopic” jumping legs is highly confusing for shrews and leads to dramatic changes in attack pattern <review> Please describe shortly in what way the attack pattern changes </review>. Thus, tactile shape cues are both necessary and sufficient for evoking attacks.
Shrews distinguish and memorize prey features and their prey representation is motion and size invariant. Shrew behavior appears to be based on the “Gestaltwahrnehmung” of crickets: they form a global construct of a cricket rather than only recognizing local elements. Thus, tactile object recognition in Etruscan shrews shares characteristics of human visual object recognition, but it proceeds faster and occurs in a 20,000-times-smaller brain.
Experience shapes tactile behavior in shrews
Little is known about the development of behavioral capacities in the somatosensory system. Three lines of evidence suggest that shrew tactile behaviors are not hard-wired but modified by tactile experience. The hunting behavior of young animals differs in subtle but significant ways from the hunting behavior of adults, whisker deprivation in young shrews disrupt the acquisition of normal hunting skills and shrews can acquire new hunting strategies in response to novel prey (Anjum and Brecht, in prep.)
The Etruscan shrew brain
Histological analyses as well as physiological techniques have been applied to assess the organization of the Etruscan shrew cortex. Based on Nissl and NeuN stains of coronal brain sections (Fig.<ref>F3</ref>, left), the number of neurons is estimated to be ~1 million per cortical hemisphere, the surface area 11 mm² per hemisphere and the volume 4.5 mm³ (Naumann, 2008). The cortex is between 300µm to 600µm thick.
The small brain size of the Etruscan shrew and its thin cortex makes this animal uniquely accessible for imaging based approaches to study brain function. In particular, using two-photon-microscopy might allow visualizing the structure and function of cortical networks in unprecedented completeness (Fig.<ref>F3</ref>, right; Roth-Alpermann, Houweling and Brecht, unpublished).
Cortical sensory areas have been delineated using multi-unit electrophysiological mapping of sensory responses (Brecht et al., submitted). Large parts of Etruscan shrew cortex (i.e. 60% of the total neocortical surface) respond to sensory stimuli. A small visual and a small auditory area have been identified. The majority of recording sites respond to tactile stimuli and more than half of these sites respond to macrovibrissae stimulation.
These findings demonstrate a remarkable degree of tactile specialization in the Etruscan shrew cortex. In comparison to other mammals studied so far, it is clear that the Etruscan shrew is one of the most extreme tactile specialists studied to date.
References
- Anjum, F., Turni, H., Mulder, P.G.H., van der Burg, J., Brecht, M. (2006). Tactile guidance of prey capture in Etruscan shrews. Proc Nat Acad Sci U S A 103(44): 16544-16549.
- Anjum, F. and Brecht, M. (in prep.) Tactile experience shapes prey-capture behavior in Etruscan shrews.
- Fons R., Sender S., Peters T., Jürgens K. D. (1997). Rates of rewarming, heart and respiratory rates and their significance for oxygen transport during arousal from torpor in the smallest mammal, the Etruscan shrew Suncus etruscus. J Exp Biol 200(Pt10): 1451-1458.
- Brecht, M., Anjum, F., Naumann, R., Roth-Alpermann, C. (submitted) Cortical Organization in the Etruscan shrew (Suncus Etruscus).
- Grünwald, A. (1969) Untersuchungen zur Orientierung der Weisszahnspitzmäuse (Soricidae – Crocidurinae). Zeitschrift für vergleichende Physiologie 65: 91-217.
- Jürgens, K.D. (2002) Etruscan shrew muscle: the consequences of being small. J Exp Biol 205(Pt15): 2161-2166.
- Naumann R.K. (2008) Neuroanatomy of the Etruscan shrew. Diploma thesis, Humboldt-University, Berlin, Germany.
External links
http://www.pnas.org/content/suppl/2006/10/16/0605573103.DC1/05573Movie1.mov Movie showing Etruscan shrew prey capture (from Anjum and Brecht, 2006)
http://www.biotact.org Research project developing novel tactile sensory technologies inspired by the vibrissal sensory systems of mammals.
http://www.activetouch.org Active touch community website
