Communicating through scents: an interview with Jane Hurst


Hurst BMC Biology          (2018) 16:126 
https://doi.org/10.1186/s12915-018-0596-2
INTERVIEW Open Access
Communicating through scents: an
interview with Jane Hurst

Jane Hurst
Abstract

Jane Hurst is a William Prescott Professor of Animal
Science at the University of Liverpool, UK, studying
scent communication in mammals and its role in
behaviours. In this interview, Jane discusses how
scents encode complex information in rodents,
driving behaviours such as kinship interactions and
choosing a mate, how understanding natural
behaviours of animals can inform experimental
designs, and what is the connection between Jane
Austen and pheromones.

Keywords: Behaviours, Scents, Olfactory
communication, MUPs, Darcin
particularly for more effective pest control?
What are the questions driving your research?
I am interested in the social organization of animals
and in the communication that mediates their inter-
actions. Much of my research has focused on scent
communication among mammals, which can be
extremely complex, with hundreds of component
molecules.
The complexity of this system and behaviours raises

many questions. For instance, what is the information
communicated through these complex scents? Ani-
mals can discriminate between individuals based on
scent, and recognize similarity in the scents of closely
related individuals. Is this based simply on the overall
similarity of body odours correlating with genetic
similarity, or have animals evolved specific scent com-
ponents that signal individual identity and kinship?
Does this differ between social and non-social spe-
cies? Do mammals use simple pheromone signals to
stimulate specific responses in conspecifics—like
Correspondence: jane.hurst@liverpool.ac.uk
Mammalian Behaviour & Evolution Group, Institute of Integrative Biology,
University of Liverpool, Liverpool, UK

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invertebrate pheromones—or do they use the infor-
mation gained through scents in a more sophisticated
way that allows them to modify their responses ac-
cording to individual experience and learning? Indi-
viduals often differ in the investment that they make
in particular components of scents—what information
does this signal?
Studies so far have focused largely on males—are there

major differences between males and females in scent
use, and how does this differ between social systems?
Also, most studies have focused on the volatile compo-
nents of scents, but we now understand that involatile
proteins and peptides play a wide variety of roles as well.
What are the selection processes determining the evolu-
tion of scent components, and how do these different
components interact? Finally, can we exploit the scent
signals that mammals use to improve their management,
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Hurst BMC Biology          (2018) 16:126 Page 2 of 3
You published several papers in BMC Biology,
including one that brought us a protein named
darcin, after a Jane Austen hero. Can you tell us a
little bit about these studies?
We wanted to understand signals in scent that underpin
mate choice: how animals assess potential mates, and
how they communicate that information. We use wild
house mice as an experimental model to ensure normal
genetic variation, as genetic compatibility, heterozygosity
and the ability to discriminate between individuals are
all important components of mate choice. Wild house
mice also appear to be a lot choosier when selecting a
mate than domesticated laboratory mice, which is per-
haps not surprising as laboratory strains have been artifi-
cially selected to breed easily.
Several androgen-dependent volatile pheromones had

been identified in male mouse urine and it was generally
assumed that females were attracted by these odours.
However, we were surprised to find that females were no
more attracted to male airborne odour than to equiva-
lent odour from another female, unless they had direct
contact with a male’s urine. This suggested that some-
thing involatile present in the male urine is essential for
the sexual attraction. But we also discovered that just a
few seconds of contact with a male’s urine stimulated fe-
males to learn a strong attraction to airborne odour
from that particular male. That led us to the hypothesis
that there is an involatile pheromone in male urine that
females find highly attractive. And, through a process of
rapid associative learning (similar to learning by Pavlov’s
dogs but much quicker), this pheromone also stimulates
subsequent attraction to the airborne odour signature of
that individual male [1]. Through subsequent analyses
we found that this involatile signal belonged to a family
of major urinary proteins (MUPs).
Because of its key importance in determining female

attraction to a male’s odour, we named the pheromone
darcin (a more memorable name than its official MGI
nomenclature as MUP20). While Jane Austen percep-
tively recognised that “it is a truth universally acknowl-
edged that a single man in possession of a good fortune
must be in want of a wife” [2], as far as male mice are
concerned, it seems that a single mouse in possession of
darcin must be in want of a mate.
Our darcin studies revealed a new mechanism of

pheromone-induced learning that modifies responses to
different individuals. Later on, we found that contact
with darcin stimulates not only short- but also long
term-learning [3] and leads to changes in the brain, in-
creasing neurogenesis in both a female’s hippocampus
and olfactory bulbs [4]. Most recently, we’ve shown that
darcin, combined with other MUPs in mouse urine,
shapes the individual odour signature that females learn
when they contact a male’s scent [5].
Looking back, is there a project that your lab
pursued that stands out for you as particularly
inspiring, tough or simply memorable?
Our darcin studies have been particularly inspiring from
a personal perspective because they have changed my
thinking about the contribution of pheromones to
learned behaviour and show how pheromones and signa-
tures of identity in scents work in concert.
But one of our most memorable studies was when we

first tried to use laboratory mice—in this case inbred
MHC-congenic strains—as a model for wild mice, in
order to identify the genetic basis of scents that underlie
the recognition of individual competitors. After years of
working with genetically heterogeneous wild rodents,
which can be difficult to handle unless approached very
carefully, I thought that working with domesticated la-
boratory strains would be a piece of cake. How wrong I
was! The caged laboratory mice would not reliably show
the normal competitive scent marking behaviour typical
of our captive wild house mice, so we decided to set them
up in floor enclosures like our wild mice to promote more
natural behaviour. As they seemed very timid, we put their
home cages in the enclosures and opened the cage lids,
leaving them to explore the enclosures at their own pace.
Wild mice normally take a few minutes to settle down
and start to explore, but the laboratory mice were reluc-
tant to leave their cages and we had to put in ladders to
encourage them to climb down and explore! After a few
weeks in the enclosures, we eventually got the competitive
scent marking that we were looking for but, even then,
needed sample sizes that were much greater than we ever
needed for wild mice, despite their genetic homogeneity.
The unexpected discovery from these studies was that la-
boratory mice can be far more anxious than I expected to
see from domesticated animals. I wanted to understand
why they were so anxious and, much to my surprise, I dis-
covered that it is because of the standard way that labora-
tory mice are handled. Almost universally, they are picked
up by the tail, but it turns out that this is strongly aversive
to mice and stimulates high anxiety. In a series of studies,
we have shown that using non-aversive handling methods
to pick up mice stimulates much less anxiety [6, 7] and
that mice handled that way can be significantly more reli-
able in behavioural testing [8]. Picking up mice using a
handling tunnel—a method we developed to handle wild
rodents with minimal stress so that they will show natur-
alistic behaviour in captivity—works particularly well.
Scooping up laboratory mice on the open hand is also less
aversive. Studies in other laboratories have confirmed our
findings and have also shown that using our non-aversive
handling methods improves reward-based learning [9]
and physiological responses such as glucose tolerance
[10]. Because picking mice up by the tail has such a strong
negative impact on mice and is likely to be a significant



Hurst BMC Biology          (2018) 16:126 Page 3 of 3
confounding factor in studies, we have made a freely avail-
able tutorial and other resources for implementing
non-aversive handling methods for normal mouse hus-
bandry and during experiments (see https://www.nc3rs.or-
g.uk/how-to-pick-up-a-mouse).

Is there a paper or a scientist that inspired you, or
was seminal for your research?
The inspiration for my research comes first and fore-
most from watching animals, a fascination I developed
from a very early age. But the inspiration to study the
behavioural ecology of wild house mice for my PhD
came from reading a book called ‘Mice All Over’ by
Peter Crowcroft (published in 1966 by Foulis, London).
After the Second World War, large grain stores were
used to stockpile food reserves. These were a magnet to
house mice, which were causing substantial spoilage. So
Peter Crowcroft and Fred Rowe, working on behalf of
the UK Government, set about trying to understand
their behaviour to be able to control these problems
more effectively. Crowcroft wrote not only about their
findings but also about how they went about their stud-
ies, and I was hooked by the idea that my fascination
with animal behaviour could contribute to research and
also have a useful purpose. I was particularly intrigued
by his accounts of a species so flexible and successful in
exploiting human resources, outwitting our attempts to
control them. So I chose to spend many hours during
my PhD watching wild house mice in agricultural build-
ings such as poultry houses, trying to understand their
social organization and how they were able to sustain
much higher population densities than other mammal
species. While poultry houses did not strike me as a
great environment from my own personal perspective,
these were clearly great for mice.
It was during these studies that I became interested in

scent communication. While watching the animals
through infrared cameras, it became clear that they were
gaining a considerable amount of information through
their noses, both from the numerous scent marks that
they were depositing around their territories and when
they interacted with each other. I realized that I would
have to understand these scent signals to understand
their behaviour. However, scent communication was a
very under-researched area despite scents providing per-
haps the most widespread means of communication be-
tween animals. This lack of knowledge, particularly in
mammals, inspired me to start my research in this area.

Website: https://www.liverpool.ac.uk/mbe/members/Hurst/
Hurst.html

Acknowledgements
Not applicable.
Funding
Not applicable.

Availability of data and materials
Not applicable.

Authors’ contributions
JH read and approved the final manuscript.

Competing interests
The author declares that she has no competing interests.

Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in
published maps and institutional affiliations.

Received: 12 October 2018 Accepted: 12 October 2018

References
1. Roberts SA, Simpson DM, Armstrong SD, Davidson AJ, Robertson DH,

McLean L, Beynon RJ, Hurst JL. Darcin: a male pheromone that stimulates
female memory and sexual attraction to an individual male's odour. BMC
Biol. 2010;8:75.

2. Austen J. Pride and prejudice. Whitehall: T Egerton; 1813.
3. Roberts SA, Davidson AJ, McLean L, Beynon RJ, Hurst JL. Pheromonal

induction of spatial learning in mice. Science. 2012;338:1462–5.
4. Hoffman E, Pickavance L, Thippeswamy T, Beynon RJ, Hurst JL. The male sex

pheromone darcin stimulates hippocampal neurogenesis and cell
proliferation in the sub ventricular zone in female mice. Front Behav
Neurosci. 2015;9:106.

5. Roberts SA, Prescott MC, Davidson AJ, McLean L, Beynon RJ, Hurst JL. Individual
odour signatures that mice learn are shaped by involatile major urinary proteins
(MUPs). BMC Biol. 2018;16:48. https://doi.org/10.1186/s12915-018-0512-9.

6. Hurst JL, West RS. Taming anxiety in laboratory mice. Nat Methods. 2010;7:
825–6.

7. Gouveia K, Hurst JL. Reducing mouse anxiety during handling. PLoS One.
2013;8(6):e66401.

8. Gouveia K, Hurst JL. Optimising reliability of mouse performance in
behavioural testing: the major role of non-aversive handling. Sci Rep. 2017;
7:44999.

9. Clarkson JM, Dwyer DM, Flecknell PA, Leach MC, Rowe C. Handling method
alters the hedonic value of reward in laboratory mice. Sci Rep. 2018;8:2448.

10. Ghosal S, Nunley A, Mahbod P, Lewis AG, Smith EP, Tong J, D’Alessio DA,
Herman JP. Mouse handling limits the impact of stress on metabolic
endpoints. Physiol Behav. 2015;150:31–7.

https://www.nc3rs.org.uk/how-to-pick-up-a-mouse
https://www.nc3rs.org.uk/how-to-pick-up-a-mouse
https://www.liverpool.ac.uk/mbe/members/Hurst/Hurst.html
https://www.liverpool.ac.uk/mbe/members/Hurst/Hurst.html
https://doi.org/10.1186/s12915-018-0512-9

	Abstract
	What are the questions driving your research?
	You published several papers in BMC Biology, including one that brought us a protein named darcin, after a Jane Austen hero. Can you tell us a little bit about these studies?
	Looking back, is there a project that your lab pursued that stands out for you as particularly inspiring, tough or simply memorable?
	Is there a paper or a scientist that inspired you, or was seminal for your research?
	Acknowledgements
	Funding
	Availability of data and materials
	Authors’ contributions
	Competing interests
	Publisher’s Note
	References