Nauplius
The Journal of The

Brazilian CrusTaCean soCieTy

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Infestation of two shrimp species of 
the genus Palaemon Fabricius, 1798 
(Decapoda, Palaemonidae) by an 
isopod of the genus Probopyrus Giard 
& Bonnier, 1888 (Bopyridae) from the 
Brazilian southeast coast

Bruno Gabriel Nunes Pralon1,2 
Mariana Antunes2 

Rafael Campanelli Mortari3  
Sérgio Luiz de Siqueira Bueno4  
Maria Lucia Negreiros-Fransozo2

1 Departamento de Biologia, Centro de Ciências da Natureza, Universidade Federal do 
Piauí (UFPI), Campus Ministro Petrônio Portella. Teresina, Piauí, Brazil.

2 Grupo de Estudos em Biologia, Ecologia e Cultivo de Crustáceos – NEBECC, 
Departamento de Zoologia, Instituto de Biociências, Universidade Estadual Paulista 
Júlio de Mesquita Filho (UNESP). Botucatu, São Paulo, Brazil.

3 Curso de Ciências Biológicas, Universidade Paulista (UNIP). Bauru, São Paulo, Brazil.

4 Departamento de Zoologia, Instituto de Biociências, Universidade de São Paulo 
(USP). São Paulo, São Paulo, Brasil.

ZOOBANK: http://zoobank.org/urn:lsid:zoobank.org:pub:6080ED4E-FEA3-4C35-
B816-906C256E6530

aBsTraCT 
We determined the infestation rate of Probopyrus sp. in populations of 
Palaemon pandaliformis (Stimpson, 1871) and P. northropi (Rankin, 1898)  
in the Ubatumirim River, localized in a mangrove ecosystem on Ubatumirim 
Beach, northern coast of the state of São Paulo, Brazil. Samplings were carried 
out monthly from April 2003 to March 2004. Monthly prevalence varied 
from 0 to 4.94 % for P. pandaliformis, and from 0 to 4.54 % for P. northropi. 
This is the first record of Probopyrus sp. infesting the studied species in this 
region. Species of Probopyrus (Giard and Bonnier, 1888) seem to have a 
high plasticity with regard to palaemonid hosts, as they can be parasites of 
shrimps in both Palaemon (Fabricius, 1798) and Macrobrachium (Spence 
Bate, 1868). The linear relationships between the parasite and host sizes 
suggest that the parasite infests both hosts early in their development. We 
concluded that the infestation of Probopyrus sp. has little impact on Palaemon 
populations, mostly due to the low prevalence of infestation. 

original arTiCle

Nauplius, 26: e2018026

CORRESPONDING AUTHOR
Bruno Gabriel Nunes Pralon
pralonbra@gmail.com

SUBMITTED 06 February 2018 
ACCEPTED 09 July 2018
PUBLISHED 03 December 2018

DOI 10.1590/2358-2936e2018026

All content of the journal, except 
where identified, is licensed under a 
Creative Commons attribution-type BY.

orcid.org/0000-0002-3733-3955

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Key words

ectoparasitism, prevalence, host, palaemonid, Brazil.

inTroduCTion

Caridean shrimps of the genus Palaemon Fabricius, 
1798 are components of estuarine food webs (Bass 
and Weis, 1999; Mortari and Negreiros-Fransozo, 
2007).   These crustaceans have their lives adversely 
affected in many ways when parasitized by isopods 
belonging to the family Bopyridae (Ocaña-Luna et 
al., 2009). 

Bopyrid isopods are obligate hematophagous ecto- 
and holoparasites of crustaceans (Chaplin-Ebanks and 
Curran, 2007; Boyko and Williams, 2009; Williams  
and Boyko, 2012). They have complex life cycles that 
require a decapod as a definitive host, and a calanoid 
copepod as an intermediate host (Anderson, 1990; 
Lester, 2005; Oliveira and Masunari, 2006; Boyko 
and Williams, 2009; Sherman and Curran, 2015). 
An adult female bopyrid is typically found attached 
to the gills inside the branchial chamber, while the 
dwarf adult male is often found attached to the ventral 
side of the female bopyrid (Beck, 1980; Choong et al., 
2011; Sherman and Curran, 2015). Parasites induce 
visible lateral swellings on the carapace of the host 
and this deformation on the branchiostegite region 
characterizes the host-parasite relationship (Choong 
et al., 2011). 

Bopyrids feed on the host’s haemolymph and 
disrupt the normal mechanical functioning of the 
gills, impairing the respiration and metabolism of 
shrimps (Choong et al., 2011; Dale and Anderson, 
1982). Shrimps parasitized by bopyrids may 
become reproductively impaired as both male and 
female individuals may become sexually sterile or 
show reduced fecundity, and male individuals can 
become somewhat become feminized due to their 
reduced chelae length (Bass and Weis, 1999). Female 
shrimps often suffer parasitic castration by having 
the full maturation of their ovaries inhibited (Rocha 
and Bueno, 2000). Thus, the deleterious effects of 
bopyrid infestation may act as an important factor 
regulating some decapod populations (Varisco and 
Vinuesa, 2011).

Among caridean shrimps, the family Palaemonidae 
is the main group with species acting as hosts for 
bopyrid isopods of the genus Probopyrus Giard 
and Bonnier, 1888, whose distribution is therefore 
tied to that of the Palaemonidae (Masunari et al., 
2000). According to Lemos de Castro and Brasil-
Lima (1974), on the Brazilian coast there are three 
species of Probopyrus: Probopyrus bithynis Richardson, 
1904, P. palaemoni Lemos de Castro and Brasil-
Lima, 1974 and P. floridensis Richardson, 1904. 
As the same authors emphasize, P. bithynis infests 
several palaemonid species, including Palaemon 
pandaliformis (Stimpson, 1871) and Palaemon 
northropi (Rankin, 1898), while P. palaemoni has been 
recorded parasitizing P. pandaliformis. Nevertheless, 
despite the wide geographical distribution and 
phylogenetic divergencies showed by P. pandaliformis 
and P. northropi (see Carvalho et al., 2017 for details), 
extending from Central America to Southern South 
America (Holthuis, 1952), these species have never 
been recorded carrying bopyrid parasite on the 
northern coast of São Paulo State, Brazil.

Palaemon pandaliformis and P. northropi are 
abundant in the estuaries located along the 
southeastern Brazilian coast (Anger and Moreira 
1998). They play an important role in the food web 
serving as prey for numerous predators. Presence of 
bopyrid ectoparasites in populations of those shrimps 
can potentially affect local reproduction. Thus, our 
study aimed to report for the first time the infestation 
of Probopyrus sp. in populations of P. pandaliformis 
and P. northropi from the Ubatuba region, northern 
coast of the state of São Paulo, Brazil. In addition, we 
commented on some aspects of their host-parasite 
relationships.

MaTerial and MeThods

Specimens of P. pandaliformis and P. northropi 
were collected monthly from April 2003 through 
March 2004, in the Ubatumirim River (23°20’17.8”S 

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44°53’2.2”W), localized at a mangrove ecosystem 
of Ubatumirim Beach, in the northern coast of the 
state of São Paulo, Brazil. The mangrove forest of 
Ubatumirim is mostly composed of vascular plants 
(i.e., Avicennia shaueriana, Laguncularia racemosa 
and Rhizophora mangle) as reported by Colpo et al. 
(2011). We conducted the samplings in the morning, 
during low tide, collecting samples within a 10 m 
stretch along the riverbank. We used a sieve (3 mm 
mesh), passing it under the submerged vegetation. 
For further information about sampling procedures 
see Mortari et al. (2009). 

We utilized plastic bags to pack samples, which 
were labeled with the date and site of the collection. 
Specimens were taken to the laboratory where they 
were identified according to Melo (2003), and 
preserved in 70% ethanol for later analysis. Voucher 
specimens were deposited in the crustacean collection 
of the Department of Zoology, IB, UNESP, Botucatu 
(NEBECC AD # 0001; AD # 0002). Carapace length 
(CL = from the posterior margin of the orbit to the 
posterior margin of the carapace) of each shrimp was 
measured under a stereomicroscope provided with a 
micrometer scale (mm). Sex evaluation was based on 
the presence (male) or the absence (non-ovigerous 
female) of an appendix masculina on the endopods of 
the second pair of pleopods.   

Parasites were identified under a dissecting 
microscope, according to available literature (Lemos 
de Castro and Brasil-Lima, 1974; Richardson, 1904). 
Photographs of the ectoparasite and its host were 
taken with a Zeiss Stemi SV6 stereoscopic microscope. 
Parasites (female and male) were measured for total 
length (TL) and width (TW) to the nearest 0.01 
mm with a stereoscopic microscope, provided with 
a micrometer scale. Male parasites are symmetrical in 
shape and were measured from the anterior edge of 
the cephalon to the posterior edge of the pleotelson, 
while females are asymmetrical in shape and were 
measured along the longest side from the anterior 
margin of the body to the end of the pleotelson 
(Cash and Bauer, 1993). Immature and mature 
parasites were differentiated according to Conner 
and Bauer (2010). The use of the term “prevalence” 
followed Margolis et al. (1982), and expressed the 

percentage of infested shrimps present in the sampled 
population. Linear regressions of parasite body size 
(TL, dependent variable) vs. host body size (CL, 
independent variable) were calculated by using the 
least square method, with a significance level of 5% 
(Wilkinson, 1988).

resulTs

We examined 2,878 P. pandaliformis (CL ranging 
from 1.5 to 5.8 mm) and 486 P. northropi (CL ranged 
from 1.9 to 9.6 mm), from which seventeen were from 
the former species (CL: 3.12 – 4.49 mm) and five 
from the latter one (CL: 3.75 – 5.74 mm) that were 
parasitized by Probopyrus sp. (Figs. 1A-B; Tab. 1). The 
monthly prevalence was low throughout the study and 
varied from 0 to 4.94% (mean value = 0.8 ± 1.39) for 
P. pandaliformis and from 0 to 4.54% (mean value = 0.8 
± 1.63) for P. northropi (Tab. 2). All bopyrid isopods 
removed from their hosts matched the morphological 
characteristics described by Richardson (1904) for 
Probopyrus sp.  (Fig. 1C). Only four parasites were 
breeding (females with eggs in the marsupium). Two 
of those specimens, obtained in November 2003, 
were parasitizing P. pandaliformis, and the other 
two, obtained in August 2003 and November 2003, 
were parasitizing P. northropi (Tab. 1). Unfortunately, 
most eggs of the breeding females were lost, so 
the determination of fecundity was not possible. 
However, we could observe that the eggs were still 
at an early stage of development, as they were full of 
yolk and with no evidence of developing embryos. 
Each female had a dwarf male of yellow coloration 
attached to its pleon (Fig. 1D). In the present study, 
infestation by Probopyrus sp. was observed mostly 
in males of P. pandaliformis (Tab. 1). We found a 
positive correlation between the TL of the parasites 
and the CL of the shrimp hosts (P. northropi n = 5; 
R2 = 0.97; p < 0.01; P. pandaliformis n = 17; R2 = 0.54; 
p < 0.01) (Fig. 2). We also found the proportion of 
parasitized specimens varied during the study period 
for both host populations. There were no bopyrids 
for at least five months of the year for either host 
species (see Tab.2).

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Figure 1. Lateral view of Palaemon northropi (A) and Palaemon pandaliformis (B) infested by Probopyrus sp. (arrow). Scale bar = 5 
mm. Female of Probopyrus sp. (dorsal view) (C). Scale bar = 1 mm. Male of Probopyrus sp. (dorsal view) (D). Scale bar: 0.5 mm. 

Figure 2. Relationship between carapace length (CL, mm) of the hosts Palaemon northropi and P. pandaliformis and total length 
(TL, mm) of their parasite, Probopyrus sp. Linear regression equation for P. pandaliformis size and probability value: TL = 1.051 
CL – 1.1306 (p = 0.0003; r2 = 0.54). Linear regression equation for P. northropi size and probability value: TL = 1.172 CL – 1.116 
(p = 0.002; r2 = 0.97).

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Host shrimp       Parasite data 
data Females Males

  Sex CL (mm) Month TL (mm) TW (mm) Developmental 
stage TL (mm) TW (mm)

P. pandaliformis M 4.48 nov/03 3.88 2.95 ovigerous
M 3.82 nov/03 2.86 2.12 ovigerous 0.72 0.18
M 3.97 nov/03 3.41 2.38 mature female 1.02 0.42
M 4.35 nov/03 3.55 3.1 mature female 1.33 0.57
M 3.21 aug/03 2.33 1.86 mature female 0.75 0.18
M 3.42 oct/03 2.67 1.82 mature female 0.82 0.27
M 3.51 oct/04 2.82 2.02 mature female 0.96 0.36
M 4.36 sep/03 3.48 2.77 mature female 1.01 0.48
M 3.58 sep/04 2.27 1.64 mature female
M 4.38 sep/04 3.63 2.74 mature female 1.16 0.54
M 3.19 sep/04 2.8 3.51 mature female 1 0.49
M 3.12 mar/04 2.45 1.81 mature female 0.74 0.18
M 4.49 jun/03 3.96 2.95 mature female 0.92 0.28
M 3.58 jul/03 1.96 1.43 mature female 0.73 0.19
M 3.71 jul/03 2.77 2.08 mature female
M 3.16 jul/03 1.98 1.46 mature female
M 3.68 jul/03 2.66 1.99 mature female

P. northropi M 4.23 dec/03 3.83 2.82 mature female 0.86 0.36
M 4.19 aug/03 4.05 2.99 ovigerous 0.95 0.45
M 3.75 aug/04 3.09 2.32 mature female
F 5.74 nov/03 5.56 3.87 ovigerous 1.61 0.63

  F 5 nov/03 4.74 3.13 mature female 1.38 0.5

Table 3. List of palaemonid shrimps infested by Probopyrus sp. (Isopoda, Bopyridae).
USA = United States of America; SP = state of São Paulo; ES = state of Espírito Santo; PR = state of Paraná.

Table 1. Number of specimens and carapace length (CL) of males (M) and females (F) of Palaemon pandaliformis and P. northropi 
infested by Probopyrus sp. Developmental stage, total length (TL) and total width (TW) of males and females of Probopyrus sp.

Date
P. pandaliformis P. northopi

N Parasite Prevalence (%) N Parasite Prevalence (%)
Mar-03 191 1 0.52 0 0 0
Apr-03 230 0 0 10 0 0
May-03 314 0 0 57 0 0
Jun-03 285 1 0.35 39 0 0
Jul-03 83 4 4.94 65 0 0

Aug-03 235 1 0.42 44 2 4.54
Sep-03 241 4 1.65 131 0 0
Oct-03 286 2 0.7 51 0 0
Nov-03 391 4 1.02 46 2 3.63
Dec-03 221 0 0 43 1 2.05
Jan-04 231 0 0 0 0 0
Feb-04 170 0 0 0 0 0

Host shrimp  Geographic location Reference
Macrobrachium potiuna Paranaguá, PR, Brazil Masunari et al., 2000
Macrobrachium potiuna Cananéia, SP, Brazil Rocha & Bueno, 2000
Palaemon northropi Ubatuba, SP, Brazil Present study
Palaemon pandaliformis Ubatuba, SP, Brazil Present study
Palaemon paludosus Florida, USA Richardson, 1904
Palaemon paludosus Guarapari, ES, Brazil Lemos de Castro & Brasil-Lima, 1974
Palaemon paludosus Florida, USA Dale and Anderson, 1982
Palaemon paludosus Georgia, USA Lemos de Castro & Brasil-Lima, 1974
Palaemon pugio Alabama, USA Sheehan et al., 2011
Unidentified palaemonid São Vicente, SP, Brazil Carvalho, 1942

Table 2. Prevalence of Probopyrus sp.  in Palaemon species at the Ubatumirim River estuary, southeast coast of Brazil.

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disCussion

We record here, for the first time, the infestation of P. 
pandaliformis and P. northropi by Probopyrus sp. on the 
southeast coast of Brazil. According to Ocaña-Luna et 
al. (2009), bopyrids of the genus Probopyrus typically 
infest palaemonid prawns from the following genera: 
Macrobrachium Spence Bate, 1868 and Palaemon. In 
South America, the association of P. floridensis with 
the host Palaemon paludosus (Gibbes, 1850) (as  
Palaemonetes exilipes) has been reported by Lemos 
de Castro and Brasil-Lima (1974), and the same 
parasite infested Macrobrachium potiuna (Muller, 
1880) according to Masunari et al. (2000), and Rocha 
and Bueno (2000). Two more palaemonid species 
are here recorded as hosts of a Probopyrus species. 
Information on host specificity of bopyrids and their 
geographic distribution are scarce for most species 
(Romero-Rodríguez et al., 2017). Even when studies 
have addressed ecological information of the hosts, 
reports about their parasites were often neglected or 
omitted (Romero-Rodríguez et al., 2017). Williams 
and Boyko (2012) mentioned that the absence of some 
parasitic groups, in certain areas, might be related to 
the lack of sampling. 

Ectoparasitism in palaemonid shrimps by Probopyrus 
sp. is not host species-specific, or even host genus-
specific, since infestations by species of Probopyrus have 
been reported for five different host species (Tab. 3). 
The same pattern  was verified for Probopyrus bithynis 
(as P. pandalicola Packard, 1879) that was recognized to 
infest several Macrobrachium species (Markham, 1985). 
Infestation on Palaemon species has  been previously 
reported for P. pandaliformis by both P. palaemoni and P. 
bithynis (Dale and Anderson, 1982; Markham, 1985). 
The latter parasite also infests P. northropi, as mentioned 
by Lemos de Castro and Brasil-Lima (1974). 

We cannot accurately identify the species of the 
Probopyrus specimens obtained, mainly because we 
only had adult individuals. Dale and Anderson (1982) 
described Probopyrus larvae from northwest Atlantic 
and found that it is possible to distinguish three species 
based on larval features: P. pandalicola, P. floridensis 
and P. bithynis. According to Markham (1985), these 
species cannot be distinguished in the adult stage.

Although the relationship of Probopyrus with a 
palaemonid host has already been reported in the 
state of São Paulo (Rocha and Bueno, 2000), our study 

expanded the distribution of this bopyrid genus, adding 
a new locality on the southeast region of Brazil, in the 
Ubatumirim River. In general, the range of distribution 
of Probopyrus sp. is narrower than that of its host species 
(Ocaña-Luna et al, 2009). In the present study, the 
distribution area of Probopyrus sp. was extended to the 
northern coast of São Paulo State, although the parasite 
distribution remains more limited than that of its hosts.

The mean prevalence of Probopyrus sp. in both 
Palaemon species hosts during monthly samplings was 
relatively low, as it was also found by Rocha and Bueno 
(2000). On the other hand, Masunari et al. (2000)
found a higher value of prevalence for P. floridensis 
in M. potiuna. According to these authors, monthly 
infestation varied from 1.1% to 91.7% throughout the 
year, when taking into account all life cycle stages of the 
parasites, in Paranaguá Bay, state of Paraná, Brazil. The 
differences between our results and those from other 
studies in the South Atlantic area might be related 
to numerous factors, such as density of cryptoniscid 
larvae, massive recruitment of hosts during specific 
periods of the year, natural mortality of shrimps, and the 
annual life cycle of the parasites. Further studies should 
be done to make a detailed examination of this host/
parasite relationship. We found that the proportion of 
parasitized specimens varied during the study period 
for both host populations. There was an absence of 
bopyrids for at least five months of the year for both 
host species. As noted by Masunari et al. (2000), we 
suspect that the reproduction of Probopyrus sp. occurs 
once a year in the Ubatumirim estuary. However, 
our data on monthly prevalence do not support the 
conclusion that the parasite’s reproduction is seasonal 
for both shrimp species from the study area.

In the present study, infestation by Probopyrus sp. 
occurred mostly in males of P. pandaliformis, differently 
from studies conducted on other carideans, in which 
parasite prevalence was either higher in female hosts 
(Chaplin-Ebanks and Curran, 2007; Rasch and Bauer, 
2015) or equivalent for both sexes ( Jarrin and Shanks, 
2008). With respect to P. northropi, it is not possible 
to conclude on its host sex-specific prevalence due 
to the low number of parasites found in the collected 
specimens. 

In other decapod species with sexual dimorphism 
associated with body size, bopyrid infestation can 
be higher in larger hosts ( Jordá and Roccatagliata, 

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Nauplius, 26: e2018026

2002). When there are no apparent morphological 
differences, the parasites may infest both sexes at the 
same proportion (Blower and Roughgarden, 1988). 
Thus, in the case of crustacean hosts, bias for males in a 
host-parasite system could be attributed to differences 
in sexual selection pressure. An experimental test 
with a copepod revealed a male-biased susceptibility 
to helminth infection attributed to sexual selection 
(Wedekind and Jakobsen, 1998). Although sexual 
selection on Palaemon species has not been detailed 
yet, a possible explanation for male bias is that males 
experience higher intra-sexual selection. Thus, their 
energetic resources are used up more rapidly, and 
this can cause a reduced ability to avoid infestation 
(Wedekind and Folstad, 1994).

Our data indicate that specimens of P. pandaliformis 
and P. northropi may be parasitized in the juvenile 
stage. The size of the hosts correlated positively with 
the size of the parasites (Fig. 2); the largest specimens 
of Probopyrus sp. (larger than 1 mm TL) were found 
in larger shrimps (larger or equal to 3.97 mm CL). 
Cryptoniscid larvae usually infest shrimps during the 
host’s early developmental stages and grow together 
with the hosts, although this is not always the case; in 
rare cases, bopyrids may infest older and larger shrimp 
hosts (Conner and Bauer, 2010). Video observations 
of P. pandalicola infesting Palaemon pugio (Holthuis, 
1949) suggest that most bopyrids must survive through 
the ecdysis of the host (Cash and Bauer, 1993). 

In summary, our results indicate that there is 
a low and variable prevalence of Probopyrus sp. on 
both sympatric host populations. Thus, it is suggested 
that these infestations may not negatively affect the 
presently studied Palaemon species. However, for 
better understanding the role played by this bopyrid 
in Palaemon population dynamics, further studies in 
the field and laboratory are still necessary. 

aCKnowledgMenTs

We thank FAPESP for financing the project 
(#98/3234-6) and the members of the NEBECC 
research group for helping with field and laboratory 
activities. We are also grateful to the anonymous 
reviewers and associate editor who provided us with 
comments on earlier versions that helped us improve the 
present manuscript, as well as English corrections. The 

sampling procedures complied with State and Federal 
laws concerning crustaceans’ samplings (ICMBio).

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