Variation in body size of Phanocerus clavicornis Sharp, 1882

(Coleoptera: Elmidae: Larainae) in Atlantic Rainforest streams in

response to hydraulic disturbance

Segura, MO.a,*, Siqueira,T.b and Fonseca-Gessner, AA.c

aDepartamento de Hidrobiologia, Universidade Federal de São Carlos, São Carlos, São Paulo, Brazil
bDepartamento de Ecologia, Instituto de Biociências, Universidade Estadual Paulista, Rio Claro, São Paulo, Brazil

cDepartamento de Hidrobiologia, Universidade Federal de São Carlos, São Carlos, São Paulo, Brazil
*e-mail: m_ottoboni@yahoo.com.br

Received July 31, 2012 - Accepted Ocdtober 23, 2012 - Distributed November 29, 2013
(With 3 figures)

Abstract

In this study, patterns of body size of Phanocerus clavicornis Sharp, 1882 (Coleoptera: Elmidae: Larainae) were inves-
tigated along a gradient of change in speed of flow conditions in streams of low order in the Atlantic Rainforest in
southeastern Brazil. Specifically, the hypothesis that the distribution of P. clavicornis larvae vary in size in response to
variations in the speed of flow in streams was tested. A Surber sampler was used to collect larvae from the streambed
during two sampling periods, defined by the rain regime: August in the dry season and February in the rainy season.
Possible differences in mean measured body size were tested by analysis of variance (ANOVA). The ANOVA result
indicated for all measurements on the larvae collected in first-order streams (head width, prothoracic width and total
body length), there were significant differences indicating a morphometric variation due to changing hydraulic condi-
tions, the smallest larvae being associated with the period of greater rainfall. However, the larger streams (3rd order),
where the rain events had less impact on the larval size, varied widely. The results of this study suggest that the intersti-
tial space is important for the protection of the larvae from water flow, and that populations of P. clavicornis have high
plasticity, a key feature for the occupation of unstable environments for this species. These results are important for an
understanding of the life history and behavioural characteristics of the species, which allow them to persist in streams
along a gradient of flow disturbance.

Keywords: aquatic insects, Brazil, flow refugia, habitat heterogeneity.

Variação no tamanho corpóreo de Phanocerus clavicornis Sharp, 1882 (Coleoptera:

Elmidae: Larainae) em córregos da Mata Atlântica sob perturbação hidráulica

Resumo

Neste estudo, padrões de tamanho do corpo de Phanocerus clavicornis Sharp, 1882 (Coleoptera: Elmidae: Larainae)
foram investigados ao longo de um gradiente de variação de velocidade da corrente em córregos de baixa ordem da
Mata Atlântica. Especificamente, buscou-se testar a hipótese de que a distribuição de larvas de P. clavicornis com
diferentes tamanhos corpóreos respondem às variações na velocidade da corrente em córregos. As coletas das larvas
foram realizadas com um amostrador de Surber durante dois períodos amostrais, definidos pelo regime de chuvas:
agosto - estação seca e fevereiro - estação chuvosa. Possíveis diferenças nas medidas de tamanho do corpo foram
testadas através de uma análise de variância (ANOVA). Os resultados da ANOVA indicaram para todas as medidas das
larvas coletadas nos córregos de primeira ordem (largura da cabeça, largura do protórax e comprimento total do corpo)
encontramos diferenças significativas, indicando uma variação morfométrica com as mudanças das condições
hidráulicas, onde as larvas menores foram associadas aos períodos de maior precipitação. No entanto, em córregos
maiores (3a ordem), os eventos de chuva tiveram menor impacto no tamanho dos indivíduos, com a ocorrência de
larvas com diferentes tamanhos. Os resultados deste estudo sugerem que os espaços intersticiais são importantes para a
proteção das larvas contra a velocidade da corrente e que as populações de P. clavicornis possuem alta plasticidade,
sendo uma característica fundamental para a ocupação desta espécie em ambientes instáveis. Esses resultados são
importantes para a compreensão da história de vida e características comportamentais da espécie, que permitem
persistir em córregos ao longo de gradiente de perturbação do fluxo.

Palavras-chave: insetos aquáticos, Brasil, refúgios, heterogeneidade ambiental.

Braz. J. Biol., 2013, vol. 73, no. 4, p. 747-752 747

felipe.esteves
Texto digitado
DOI: 10.1590/S1519-698420130004000010



1. Introduction

In streams and rivers, hydraulic conditions can play a
key role in the distribution of organisms, through direct
effects, such as flooding and drag forces (Weissenberger
et al., 1991; Collier et al., 1995) and indirect effects, such
as those of stream flow on the substrate particles (Jowett
et al., 1991) and food availability (Biggs and Hickey,
1994; Hart and Finelli, 1999). Variations in hydraulic
conditions, especially current flow, can also disturb the
fauna by removing or killing organisms (Townsend and
Hildrew, 1994) and affecting reproduction rates, thus
creating new opportunities for individuals to settle (Sou-
sa, 1984). The impact of the resulting changes in resource
availability and the substrate can be measured by the eco-
logical responses of organisms (White and Pickett, 1985;
Poff, 1992). For example, in temporally stable habitats
species with long life spans and large body sizes can be
found (Towsend and Hildrew, 1994).

The vulnerability of organisms to intense current
flow can be reduced by morphological adaptations of the
body or behavioural mechanisms such as the use of
refugia (Statzner and Holm, 1989; Sedell et al., 1990;
Sagnes et al., 2008). In streams, the irregular surface of
inorganic substrates (Holomuzki and Biggs, 2003),
leaves and wood debris (Palmer et al., 1996) often pro-
vide refuges from the current flow and enable survival
during a disturbance (Lancaster et al., 2006). In adverse
conditions, refuges can protect organisms that will later
reoccupy the areas affected (Rempel, 1999). Research on
the influence of current flow and the search for refugia
and how they affect the functional attributes of inverte-
brates has recently become more prominent (e.g, Sibly
and Calow, 1989; Sedella et al., 1990; Lancaster and
Hildrew, 1993; Winterbottom et al., 1997; Franken et al.,
2006). These studies suggest that the use of refugia plays
a key role in determining the species composition and
functional characteristics of benthic communities.

The event of high discharge in streams is known as
the main disturbance affecting the structure of macro-
invertebrate communities (Melo et al., 2003). In this
study, we investigated patterns of body size of
Phanocerus clavicornis Sharp, 1882 (Coleoptera:
Elmidae: Larainae) along a gradient of change of stream
flow. The effects of such disturbance can vary in relation
to the body size of each organism: smaller individuals are
more able to resist being washed away and/or survive un-
der conditions associated with increased flow.

Phanocerus clavicornis was used as a model in our
study because it is very frequently and abundantly found
in streams of the Atlantic Rainforest in southeastern
Brazil. Both larvae and adults of P. clavicornis are
aquatic and found in the same environment (Brown,
1987; Spangler and Santiago-Fragoso, 1992) - in riffles,
under rocks and accumulated leaves in shallow streams
of clear and cold water (Spangler and Santiago-Fragoso,
1992). It is a widely distributed species, with records
from southeastern Texas (USA) (Spangler and Santi-
ago-Fragoso, 1992) to South America. In Brazil there are

records of its occurrence in the Northern (Passos et al.,
2010), Southern (Santa Catarina; Hinton, 1937) and
Southeastern (São Paulo, Segura et al., 2011; Segura et
al., 2012 and Rio de Janeiro, Passos et al., 2009) regions.

In this study, we assumed a direct relationship be-
tween the velocity of stream flow and seasonality, the
flow being slower during the dry season than the rainy.
We tested the hypothesis that Phanocerus clavicornis

larvae have different body sizes in response to different
current flow in streams of low order in the Atlantic Rain-
forest. Specifically, in the period of faster flow - the rainy
season - the larvae of P. clavicornis would have a smaller
body than in the period of slower flow - the dry season.

2. Material and Methods

2.1. Study area and sampling

The study was conducted in streams in the Parque
Estadual de Campos do Jordão (PECJ), in Campos do
Jordão, southeastern Brazil (22°30’-22°41’ S by 45°27’-
45°31’ W) (Figure 1). The Park, covering 8,385 ha, in-
cludes areas of Dense and Mixed Rainforest and high-
altitude fields of grass. The average elevation is 1,650 m
and the highest point is situated at 1,900 m above sea
level (Seibert, 1975) (Figure 1). The climate is humid and
cool with concentrated rain between the months of Octo-
ber and February and less frequent rain between March
and September (Seibert, 1975). Figure 2 shows the
monthly variation of rainfall in the Park area during the
study period, clearly slowing the seasonality described
above.

In PECJ there is a dense network of tributary streams,
which drain into the Sapucaí-Guaçu River basin. The

748 Braz. J. Biol., 2013, vol. 73, no. 5, p. 747-752

Segura, MO., Siqueira,T. and Fonseca-Gessner, AA.

Figure 1 - Geographic location of Parque Estadual de Cam-
pos do Jordão, São Paulo state, Brazil.



streams have mountain characteristics, with a streambed
of gravel, stones, sand and fine sediments and cold, clean
and oxygenated water.

Phanocerus clavicornis larvae were collected in six
low order streams (1st and 3rd) in areas of riffles with ac-
cumulation of leaves: three streams of first order (aver-
age width: 1.31 � 0.46 m and average depth: 0.12 �

0.08 m) and three streams of third order (average width:
2.85 � 0.677 m and average depth: 0.26 � 0.051 m).

Sampling occurred on two occasions, in the month of
August, in the period of low rainfall (47.2 mm), and Feb-
ruary, during the rainy season (253.8 mm) (Figure 2). In
each stream five samples were collected from leaves in
riffles, totalling 30 samples per period. The material was
sampled with a Surber collector of reduced area (area of
0.0361 m2, 0.25 mm mesh). The material collected was
fixed in 4% formaldehyde on site and transported to the
laboratory, where it was washed on a mesh of 0.25 mm,
sorted under a stereomicroscope and preserved in 80%
ethanol. The material is deposited in the collection of the
Aquatic Insect Laboratory of the Universidade Federal
de São Carlos (Brazil).

2.2. Body size

For each larva, linear measurements of the greatest
width of head (including eyes), prothoracic width (near
the line of insertion of mesothoracic) and total body
length were recorded (Figure 3). Measurements were
taken through a magnifying glass coupled to a Leica DFC
295 digital camera. Thirty individuals per sample were
measured.

2.3. Statistical analysis

Possible differences in body size were tested by ap-
plying analysis of (ANOVA). We first tested the normal-
ity of the data by the Shapiro-Wilk test and homogeneity
of variance by Levene’s test. Since the data did not show

a normal distribution - not even after logarithmic trans-
formation - we used a nonparametric ANOVA. P-values
were obtained by permutation tests (999 permutations),
following the procedure proposed by Pierre Legendre
(available at: http://www.bio.umontreal.ca/legendre/)
and implemented in program R (R Development Core
Team, 2010).

First we used a two-way ANOVA to test the exis-
tence of interaction between the factors (a) current flow
in the two climatic periods (dry and rainy) and (b) length
of streams (1st order and 3rd order). If a significant inter-
action was found, we would analyse the effect of current
flow factor on the body size separately in streams of the
first and third orders, by one-way ANOVA. For all tests,
we used a statistical significance of p � 0.05.

3. Results

We found differences in all measurements of larvae
(i.e., body size, width of the head and base of protho-
racic) with respect to the stream current flow factor, but
not with respect to the stream order factor (Table 1). As a
significant interaction between factors was found, we de-
cided to analyse the effect of the flow rate factor in
streams of the first and third orders separately, by one-
way ANOVA. This interaction between factors indicates
that the effect of flow rate on size depends on the size of

Braz. J. Biol., 2013, vol. 73, no. 4, p. 747-752 749

Variation in body size of Elmidae

Figure 2 - Variation in rainfall from July/2005 to April/2006
in the Parque Estadual de Campos do Jordão, São Paulo,
Brazil. The arrows indicate the periods of sampling. Data
provided by Weather Station No. 83,714, 7thDistrict of Me-
teorology of the Ministry of Agriculture, Parque Estadual de
Campos do Jordão, SP, Brazil.

Figure 3 - Phanocerus clavicornis Sharp, 1882 larva in dor-
sal view, showing the structures measured for analysis. (A)
Head width, (B) width of the prothoracic and (C) body
length. Illustration: Adapted from Passos et al. (2007).



the stream, i.e., there may be an effect in streams of a
given order, but not in streams of another order.

In the one-way ANOVA, we also found differences
in all measurements of the larvae (size of body, head and
base of prothoracic) in first-order streams, while in the
third-order streams, differences were found only in pro-
thoracic width measurements, between the periods of
low and high flow (Table 2). In first-order streams, the
larvae were smaller in the season of high flow than those
collected in the period of low flow. In third-order
streams, the P. clavicornis larvae were of equal size in
the two periods.

The average size for all measurements was smaller in
high rainfall and larger during low rainfall, but sizes var-
ied greatly in both periods.

4. Discussion

In streams, current flow fluctuations are a source of
disturbance to benthic communities. Thus, a local or tem-
porary increased flow can disrupt the bed, which can
have negative effects, ending the permanence of benthic
organisms, causing immediate death or an unfavorable
drift downstream (Collier et al., 1995; Lancaster and
Beyea, 1997). Our results suggest that larvae of P.

clavicornis have different body sizes in response to
changes in current flow in the low-order streams of the
Atlantic Rainforest.

This study was designed to assess the effects of natu-
ral hydraulic disturbance on larvae of aquatic Coleoptera.

Our initial hypothesis that rainfall events would influ-
ence the body size of the larvae of P. clavicornis in first
and third-order streams has not been completely con-
firmed. Analysis of the results showed that rainfall events
can influence the size of larvae of P. clavicornis in
smaller streams (1st order). For all the measurements on
the larvae (head width, prothoracic width and total body
length), significant differences were found, indicating a
morphometric variation caused by changing hydraulic
conditions, in which the smallest larvae were associated
with the period of greater rainfall. Similar results were re-
ported in a previous study in a river in Australia, where,
after a major flood, the invertebrates were smaller
(Thomson, 2002). Benthic invertebrates depend on the
characteristics of the substrate for the availability of pro-
tected places under rocks and in cracks to prevent hy-
draulic stress (Lancaster and Hildrew, 1993). Reduced
body size is favoured in adverse hydraulic conditions be-
cause smaller larvae can penetrate substrates of low po-
rosity, in small interstitial spaces that serve as refugia
against current displacement (Townsend and Thompson,
2007). In adverse conditions, organisms in these shelters
are more likely to survive and later re-colonise the af-
fected areas. The active search by macroinvertebrates for

750 Braz. J. Biol., 2013, vol. 73, no. 5, p. 747-752

Segura, MO., Siqueira,T. and Fonseca-Gessner, AA.

Table 1 - Two-way Anova results for (a) total body size, (b)
head length and (c) width of the prothoracic of Phanocerus

clavicornis Sharp, 1882 larvae found in first and third-order
streams, in rainy and dry periods.

Df MS F p

(a) body size

Period 1 4.242 24.288 0.001

Stream order 1 0.26 1.492 0.203

Interaction 1 0.834 4.777 0.026

Residual 341 0.174

(b) head

Period 1 1.432 17.503 0.001

Stream order 1 0.134 1.643 0.194

Interaction 1 0.249 3.055 0.095

Residual 341 0.081

(c) prothoracic

Period 1 5.861 35.88 0.001

Stream order 1 0.21 1.288 0.242

Interaction 1 0.746 4.568 0.03

Residual 341 0.163

Note: df: degrees of freedom; MS: mean squared deviation.

Table 2 - One-way Anova results for effect of season on (a)
total body size, (b) head length and (c) width of the protho-
racic of larvae from first and third-order streams.

Df MS F p

First order stream

(a) body size

all factors 1 4.35 25.397 0.001

Residual 168 28.781

(b) head

all factors 1 1.416 17.201 0.001

Residual 168 13.839

(c) prothoracic

all factors 1 5.311 31.226 0.001

Residual 168 0.17

Third order stream

(a) body size

all factors 1 0.667 3.751 0.058

Residual 173 30.775

(b) head

all factors 1 0.246 3.034 0.093

Residual 173 14.061

(c) prothoracic

all factors 1 1.231 7.854 0.008

Residual 173 27.13

Note: df: degrees of freedom; MS: mean squared deviation.



shelter during high-flow events was confirmed in obser-
vations made during simulated floods in tanks (Holo-
muzki and Biggs, 2000). In this simulation, immature
Ephemeroptera and Trichoptera made small movements
between the layers of the substrate as the flow increased.

On the other hand, Merigoux and Dolédec (2004)
analysed streams in southern France, and obtained the
opposite results to those reported here. Larger body sizes
were found predominantly under extreme hydraulic
stress. They argued that morphological and behavioural
characteristics such as the ability to cling to the substrate
may be enhanced, according to the size of the individual
thus, overcoming the disadvantage due to larger size. Our
results suggest that in third-order streams there may be a
balance between a better use of refugia by smaller larvae
and greater ability to settle on the substrate by larger lar-
vae. In these streams we observed the largest ranges of
body size with both lowest and highest limits in periods
of higher water flow.

Our initial hypothesis was not confirmed for the
larger streams (3rd order), where the rain events had less
impact on the larval size, which varied widely. These re-
sults can be explained by the greater stability of larger
streams. The size of the stream is undoubtedly one of the
fundamental factors determining the structure of lotic
ecosystems (Vannote et al., 1980). In natural systems, the
fluctuations of the channel decrease as the order of the
river and spatial heterogeneity increase, resulting in a
more stable community in the larger rivers (Harrel and
Dorris, 1968; Allan and Castilho, 2007). This suggests
that in lotic systems, areas of greater spatial heterogene-
ity are less disturbed by temporal variations (Townsend
and Hildrew, 1994) and can provide not only a greater
number of habitats, but also a greater number of refugia
(Sedell, 1990; Rempel, 1999). Also, Matthaei and
Townsend (2000) report that bigger individuals of
Hydora sp. (Elmidae: Larainae) were found in more sta-
ble areas in rivers in New Zealand. The results of this
study validate the idea that larger shelters in larger
streams are qualitatively different from those in small
streams (Rempel, 1999).

5. Conclusion

Our results suggest that populations of Phanocerus

clavicornis have great phenotypic plasticity, a key fea-
ture for the occupation of unstable environments by this
species. This is probably one explanation for its success
in the streams and rivers of the Atlantic Rainforest, where
variations in the velocity of the current flow during larval
development may reduce the fitness of individuals and
the population size. These results are important for an un-
derstanding of the life history and behavioural character-
istics of the species, which allow them to persist in
streams along a gradient of flow disturbance. Also, there
was evidence of overlapping P. clavicornis generations,
since we found a wide variation in body size during the
periods studied, with mature and young larvae in the
same period.

Acknowledgments

We are grateful to Dr. Marcia Regina Spies and Dr.
Ana Emília Siegloch for helping to collect specimens, to
Dr. Luciana Bueno dos Reis Fernandes for helping with
some photos and Dr. Neusa Hamada for technical sup-
port (Pronex- CNPq/FAPEAM). We also thank Fran-
cisco Valente Neto and Gustavo Rincon Mazão for valu-
able comments during the elaboration of this study. The
authors wish to thank the São Paulo State Research Foun-
dation (FAPESP) and the Coordinating Office for the
Advancement of Higher Education (Capes) for financial
support.

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