Hiebert, T.C. 2015. Ligia pallasii. In: Oregon Estuarine Invertebrates: Rudys' Illustrated Guide to Common Species, 3rd ed.  
T.C. Hiebert, B.A. Butler and A.L. Shanks (eds.). University of Oregon Libraries and Oregon Institute of Marine Biology, 
Charleston, OR. 
 
 
 
 
 
 
Taxonomy: The genus Ligia was very briefly 
called Ligyda in the early 1900s.  Since then, 
the genus has been split into four genera 
(Geoligia, Megaligia, Nesoligia and Ligia) 
based on morphological characters (e.g. 
antennulae, mouthparts, telson) (Jackson 
1927).  However, Van Name reduced these 
genera to subgeneric status and reinstated 
the genus Ligia in 1936 (Brusca 1980).  
Currently, these subgeneric names are rarely 
used and, instead, researchers refer to Ligia 
pallasii (e.g. Brusca et al. 2007).    
 
Description 
Size:  To 35 mm in length (including uropods, 
which are 3 mm long) and approximately 11 
mm wide (Brusca and Brusca 1978).  The 
figured specimen (from Coos Bay) is 22 mm 
long.  
Color:  Mottled gray and often brown, with 
granular surface. 
General Morphology:  Isopod bodies are 
dorso-ventrally flattened and can be divided 
into a compact cephalon, with eyes, two 
antennae and mouthparts, and a pereon 
(thorax) with eight segments, each bearing 
similar pereopods (hence the name “iso-
pod”).  Posterior to the pereon is the pleon, or 
abdomen, with six segments, the last of which 
is fused with the telson (the pleotelson) (see 
Plate 231, Brusca et al. 2007).  The Isopoda 
can be divided into two groups:  ancestral 
(“short-tailed”) groups (i.e. suborders) that 
have short telsons and derived (“long-tailed”) 
groups with long telsons, L. pallasii groups 
among the former (see Fig. 3, Garthwaite and 
Lawson 1992; Brandt and Poore 2003; Plate 
248C, Brusca et al. 2007).  The suborder to 
which L. pallasii belongs, Oniscidea, is the 
largest isopod suborder and the only fully-
terrestrial crustacean group (Brusca et al. 
2007). 
Cephalon:  More than twice as wide as long 
with rounded anterior margin and without 
lobes (Fig. 1) (family Ligiidae, Brusca et al. 
2007). 
  
Rostrum:  
 Eyes:  Large, round, composite, and 
close to lateral margin (Fig. 1) (Welton and  
Miller 1980).  Separated in front by twice the 
length of the eye. 
 Antenna 1:  First antennae are 
vestigial (Oniscidea, Brusca et al. 2007).  
 Antenna 2:  Second antennae reach 
to middle of fourth thoracic segment (Fig. 1).  
The second antennae are with peduncles of 
five articles:  the first two are short, the third is 
twice as long as the second, the fourth is 1½ 
x longer than the third, and the fifth 1½ x 
longer than the fourth (Welton and Miller 
1980).  The flagellum has 15 articles (Hatch 
1947). 
 Mouthparts:  In order from outside of 
buccal cavity:  maxillipeds with palp of five 
articles (Fig. 8), second maxillae with two 
plumose processes on inner side of lobe (Fig. 
5), first maxillae with three plumose 
processes on the inner lobe (Fig. 4), and the 
mandible with large, broad molar surfaces, 
and no palp (Fig. 3).  
Pereon:  First segment fused with head 
followed by seven free pereonites.  Contains 
a tubular heart and cardiac ganglion 
consisting of six neurons (see Fig. 1, Sakurai 
and Wilkens 2003).   
 Pereonites:  First four pereonites are 
subequal, last three are somewhat shorter 
along medial line and extend downward 
laterally.  Epimera (flattened lateral 
extensions to pereonites) form broad plates, 
especially in males (Figs. 1, 4). 
 Pereopods:  Seven pairs of delicate 
walking legs.  Carpus and merus of first pair is 
swollen and not grooved (Hatch 1947).  
Pleon:  Pleon as wide as thorax and with five 
free pleonites and a short pleotelson (Fig. 1). 
 Pleonites:  First two pleonites narrow 
and without downwardly extending lateral 
edges, which mark last three segments (Fig. 
1). 
 Pleopods:  Paired breathing 
appendages beneath pleonites have whitish 
Ligia pallasii 
A rock louse or shore isopod  
Phylum:  Arthropoda, Crustacea    
   Class:   Malacostraca 
      Order:  Isopoda, Oniscidea 
         Family:  Ligiidae 
   
 
A publication of the University of Oregon Libraries and the Oregon Institute of Marine Biology 
Individual species: http://hdl.handle.net/1794/12719 and full 3rd edition: http://hdl.handle.net/1794/18839  
Email corrections to: oimbref@uoregon.edu 
 
 
 
 
 
 
 
 Hiebert, T.C. 2015. Ligia pallasii. In: Oregon Estuarine Invertebrates: Rudys' Illustrated Guide to Common Species, 3rd ed.  
T.C. Hiebert, B.A. Butler and A.L. Shanks (eds.). University of Oregon Libraries and Oregon Institute of Marine Biology, 
Charleston, OR. 
tissue.  Male genitalia, paired but not fused, is 
present on second pleopods (Fig. 7). 
Uropods:  Terminal and styliform, with bases 
about as long as wide.  No process at inner 
distal margin of basal joint (Fig. 6), uropod 
rami equal and about twice the length of the 
peduncle (less than 1/2 total body length, 
Ligia, Hatch 1947). 
Pleotelson:  Rounded on middle of posterior 
edge and postero-lateral projections not quite 
as long as middle (Fig. 1). 
Sexual Dimorphism:  Males with penial 
processes on second pleopods, and with 
wide epimera (Fig. 2).  Females, when 
ovigerous, with oöstegites.  Mature males are 
larger and broader than females (Carefoot 
1973a, but see Kozloff 1993). 
 
Possible Misidentifications  
The order Isopoda contains 10,000 species, 
1/2 of which are marine and comprise 10 
suborders, with eight present from central 
California to Oregon (see Brusca et al. 2007).  
Among isopods with small, short telsons, 
there are several groups (i.e. suborders) 
including Phreatoicidea, Asellota, 
Microcerberidea, Calabozoidea and 
Oniscidea. 
 The monophyletic Oniscidea 
(previously part of the paraphyletic 
Scyphacidae, see Holdrich et al. 1984 in 
Schmidt 2000, 2002) is a fully-terrestrial 
group composed of 4,000 described 
species, with 22 known locally (among 10 
families, Schmidt 2002; Brusca et al. 2007).  
Members are characterized by seven 
pereonites, the first not fused with the head, 
seven pairs of pereopods, male penes on 
the sternum of pereonite seven, a 
pleotelson that does not curve dorsally, 
vestigal (or very small) antennules and a 
pleon with five free pleonites (Brusca et al. 
2007).  The first and second pleopods are 
also elongated in males for copulation, 
many species have a water conducting 
system and some have respiratory 
structures on pleopods called 
pseudotracheae.  The Oniscidea can be 
divided into three major ecological groups:  
the runners (slender bodies with long 
pereopods, the clingers (broad bodies with 
short pereopods) and the rollers (convex 
bodies that roll into balls) (Schmalfuss 1984 
in Brusca et al. 2007).  Ligia pallasii are fast 
runners (Brusca 1980). 
 The Ligiidae are usually littoral, they 
can swim, but in our area are restricted to 
the upper littoral (spray) zone (Hatch 1947).  
They have terminal uropods that are 
conspicuous dorsally, flagellum antenna 
with more than 10 articles and eyes with 
more than 50 ommatidia each (Brusca et al. 
2007).  The Ligiidae can further be 
distinguished from the other oniscidean 
families by having more than four articles in 
the flagellum of the second antennae, and 
by their lack of anterolateral head lobes.  
This family is represented by four local 
species, two in the genus Ligia, including L. 
occidentalis and L. pallasii and two in the 
genus Ligidium, including L. gracile and L. 
lactum.  The former genus is semi-terrestrial 
and occurs in higher intertidal marine 
habitats, while the two latter species occur 
in riparian habitats (Brusca 1980; Brusca et 
al. 2007).  Ligidium species have uropods 
with processes at the inner distal margin, to 
articulate the endopod (Ligia species do 
not).  The genus Ligia is characterized by a 
pleotelson that bears posterolateral 
projections (see Fig. 1) and a uropod that 
has endo- and exopod insertions at the 
same level (Ligidium species lack these 
projections) (Brusca et al. 2007).    
 The species closest to L. pallasii on 
the northeastern Pacific shore is Ligia 
occidentalis, an inhabitant mostly of rocky 
outer shores, which, like L. pallasii, is often 
found near fresh-water seeps (Wilson 1970).  
It can tolerate greater extremes of dryness 
than L. pallasii.  The two species can be 
distinguished morphologically.  Ligia 
occidentalis is narrower than L. pallasii, 
being over twice as long as wide and its eyes 
that are closer together, about one eye's 
length apart (Garthwaite and Lawson1992).  
Furthermore, its uropod bases are several 
times longer than broad (L. pallasii's are 
almost square) (Brusca et al. 2007).  Its 
second antennal flagella are longer, 
extending to the sixth thoracic segment, and 
contain 29 articles, not 15.  This species 
occurs on rocky shores, from Oregon south 
(Brusca et al. 2007). 
 
 
 
 
A publication of the University of Oregon Libraries and the Oregon Institute of Marine Biology 
Individual species: http://hdl.handle.net/1794/12719 and full 3rd edition: http://hdl.handle.net/1794/18839  
Email corrections to: oimbref@uoregon.edu 
 
Ecological Information 
Range:  Known range includes western 
Aleutians south to Santa Cruz, California 
(Welton and Miller 1980).  Across this range, 
there are three distinct clades (mitochondrial 
COI sequence data) and, within those clades, 
lower latitudes show greater divergence than 
those at northern latitudes (Eberl 2013). 
Local Distribution:  Oregon sites include 
estuaries at Coos and Depoe Bay and 
Florence, as well as outer shores (Hatch 
1947). 
Habitat:  Outer shore in deep crevices, under 
ledges, and near freshwater seepage. 
Estuarine habitats in hard-packed beaches, 
pilings, docks, as well as rocks.  Individuals 
cannot tolerate extreme wetting or drying for 
extended periods and are often found in cool, 
moist conditions (Wilson 1970), preferring 
shaded rocky cliffs and caves (Ricketts and 
Calvin 1952; Eberl 2012) along the open 
coast (Garthwaite and Lawson 1992).  Young 
individuals prefer moist macroalgae, 
particularly Enteromorpha (Carefoot 1979).  
Phylogenetically, isopods in the genus Ligia 
are thought to be in evolutionary transition 
from sea to land environments.  Thus, they 
have a variety of unique physiological traits 
associated with each habitat (Wilson 1970; 
Zimmer 2002).  The composition of 
respiratory proteins, hemocyanin present in L. 
pallasii have been described (see Terwilliger 
1982).   
Salinity:  Found in full salt water habitats, but 
near fresh water seeps.  Individuals can 
osmoregulate well and are found in areas of 
variable salinity (Wilson 1970).  Ligia pallasii 
has been the subject of some toxicity 
research (e.g. Carefoot 1990a, b). 
Temperature:  Does not tolerate extended 
heat or drying, lives permanently in cool moist 
habitats (Wilson 1970). 
Tidal Level:  Individuals reported living on 
cliffs that are 1.5–6 meters above tide level  in 
Moss Beach, California.  In estuarine beaches 
of South Slough in Coos Bay, individuals are 
found at about 1.5 meters.  
Associates:  Beach wrack and wood debris 
associates include isopods Limnoria, and 
amphipods Orchestia and Orchestoidea.  
Ligia species L. pallasii and L. occidentalis 
both host mycoplasma-like symbionts that are 
believed to have aided in the sea to land 
transition among the Oniscidea (Eberl 2010).   
Abundance:  Ligia pallasii is the most 
common Ligia species on extreme northern 
California coast (Brusca and Brusca 1978).  
Abundant along the open coast from Alaska 
to San Francisco, California (Kozloff 1993).   
Life-History Information 
Reproduction:  Most isopods have separate 
sexes (i.e. dioecious, Brusca and Iverson 
1985) (although protogynous and protandric 
species are known, Araujo et al. 2004; Boyko 
and Wolff 2014).  Reproduction proceeds by 
copulation and internal fertilization where 
eggs are deposited within a few hours after 
copulation and brooded within the female 
marsupium (Brusca and Iverson 1985). The 
biphasic molting of isopods allows for 
copulation; the posterior portion of the body 
molts and individuals mate, then the anterior 
portion, which holds the brood pouch, molts 
(Sadro 2001).  Embryonic development 
proceeds within the brood chamber and is 
direct with individuals hatching as manca 
larvae that resemble small adults, with no 
larval stage (Boyko and Wolff 2014).  Gravid 
L. pallasii females have been observed year-
round (Ecola State Park, Oregon to Ventura 
California, Eberl 2012).  Females are found 
with young in early spring through summer 
(April to May) in Coos Bay and females with 
broods were collected in July in Mora, 
Washington (Ricketts and Calvin 1952).  The 
average brood size is 48 ±11 (Carefoot 
1973a; Welton and Miller 1980).    
Larva:  Since most isopods are direct 
developing, they lack a definite larval stage.  
Instead this young developmental stage 
resembles small adults (e.g. Fig. 40.1, Boyko 
and Wolff 2014).  Most isopods develop from 
embryo to a manca larva, consisting of three 
stages.  Manca larvae are recognizable by 
lacking the seventh pair of pereopods, but 
otherwise resemble small adults.  They 
usually hatch from the female marsupium at 
the second stage and the molt from second to 
third manca produces the seventh pair of 
pereopods and sexual characteristics (Boyko 
and Wolff 2014).  Isopod development and 
larval morphology can vary between groups 
(e.g. Gnathiidae, Cryptoniscoidea, 
Bopyroidae, Cymothoidae, Oniscoidea) (see 
Boyko and Wolff 2014).  Parasitic isopods, for 
example, have larvae that are morphologically 
dissimilar from adults (Sadro 2001).  Isopod 
larvae are not common members of the 
plankton, and parasitic larvae are most likely 
 Hiebert, T.C. 2015. Ligia pallasii. In: Oregon Estuarine Invertebrates: Rudys' Illustrated Guide to Common Species, 3rd ed.  
T.C. Hiebert, B.A. Butler and A.L. Shanks (eds.). University of Oregon Libraries and Oregon Institute of Marine Biology, 
Charleston, OR. 
to be observed.  Occasionally, suspended 
benthic juveniles or pelagic species are 
collected in plankton samples, but these can 
be differentiated from larvae by their larger 
size (Sadro 2001). 
Juvenile:  Young individuals are 
approximately 2–5 mm in length after release 
from the female brood pouch (Carefoot 1979).  
Individuals reach sexual maturity after one 
year (Carefoot 1973a).   
Longevity:  1.5–2 years (Carefoot 1973a; 
Welton and Miller 1980). 
Growth Rate:  Growth among isopods occurs 
in conjunction with molting where the 
exoskeleton is shed and replaced.  Post-molt 
individuals will have soft shells as the cuticle 
gradually hardens.  During a molt, arthropods 
have the ability to regenerate limbs that were 
previously autonomized (Kuris et al. 2007), 
however, isopods do not autotomize limbs as 
readily as other groups (Brusca and Iverson 
1985).  Compared to other arthropods, 
isopods exhibit a unique biphasic molting, in 
which the posterior 1/2 of the body molts 
before the anterior 1/2 (Brusca et al. 2007).  
The hemolymph ion composition of L. pallasii 
has been documented throughout several 
molting stages and concentrations of Ca2+ 
and K+ changed most significantly over the 
course of a a molt (Siegler et al. 2000).   
Food:  A scavenger, feeding mostly on 
decayed algal material as well as animal 
detritus (Kozloff 1993; Brusca and Brusca 
1978).  Individuals showed preference to 
aged and decaying beach wrack over fresh 
macroalgae of the same species (Pennings et 
al. 2000).  Food gathering is restricted to cool, 
humid periods (Wilson 1970) and includes 
diatoms, insect larvae and macro algae (e.g. 
Ulva sp., Nereocystis leutkeana) (Carefoot 
1973b).  With a daily energy budget of about 
14 J per 250 mg per isopod, L. pallasii 
individuals require at least 11 mg of seaweed 
to survive, which takes about 35 minutes to 
ingest (Carefoot et al. 2003).  
Predators:  Birds, humans (e.g. for fish bait) 
and Pachygrapsus crassipes (Welton and 
Miller 1980).  Isopods play a significant role 
as intermediate food web links, like 
amphipods, (e.g. see Americorophium 
salmonis, this guide) that are consumed by 
more than 20 species of marine fish (Welton 
and Miller 1980; cabezon, Best and 
Stachowicz 2012) and whales (Brusca et al. 
2007). 
Behavior:  Uropod rami are dipped into pools 
to obtain moisture for gills (pleopods) (Brusca 
and Brusca 1978).  The energy budget of L. 
pallasii can be divided as follows:  0.56 J for 
resting, 1.36 J for feeding, 1.31 J for running, 
0.96 J for molting and 0.57 J per 250 mg per 
individual per hour for brood-carrying 
(Carefoot et al. 2003 
 
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