DOI: 10.13102/sociobiology.v67i3.4950Sociobiology 67(3): 408-416 (September, 2020) 

Open access journal: http://periodicos.uefs.br/ojs/index.php/sociobiology
ISSN: 0361-6525

Introduction

Apis mellifera can be affected by two species of 
microsporidia (Nosema apis and Nosema ceranae), which 
cause the disease called nosemosis or nosemose, with different 
field symptoms and seasonal prevalence (Fries et al., 2006, 
2013, Higes et al., 2008). The current diagnostic techniques 
include light microscopy to confirm the presence and intensity 
of infection and molecular tools to distinguish Nosema species 
(Paxton et al., 2007; Fries et al., 2013) or to quantify nucleic 
acids of the species that are present (Cilia et al., 2018).

Abstract
Nosemosis is an important disease that affects honey bees (Apis mellifera Lineu), caused 
by obligate intracellular parasites, Nosema apis and/or Nosema ceranae. Since the 
initial detection of N. ceranae in A. mellifera coincided with recent large-scale losses of 
bee colonies worldwide, the impacts of this parasite under field conditions are of great 
interest. Here we test two hypotheses, the first one, whether the climatic variables 
(temperature, air humidity and precipitation) influence the intensity of infection of the 
microsporidium Nosema spp. in Africanized honey bees (Apis mellifera), and the second, 
whether the local of hive installation (outdoor or roofed) influences the intensity of 
infection of these spores in Africanized honey bees. Between August 2013 and August 
2016, samples of Africanized bees were collected weekly from 20 colonies, of which ten 
were located in an open area (outdoor apiary) and ten under a roof on a concrete floor 
(roofed apiary). N. ceranae was the only species present. The type of apiary did not 
influence (p > 0.05) the number of spores of N. ceranae in Africanized bees. However, 
the infection intensities of the roofed apiary colonies were lower in the autumn. 
Regarding the meteorological parameters, there was a negative correlation between 
the winter infection intensities and the minimum temperature in the roofed apiary and 
the humidity in the outdoor apiary. The highest infection intensities occurred in both 
apiaries in the spring and summer, which may be related to higher pollen production. 
On average, the infection intensity was 16.19 ± 15.81 x 105, ranging from zero to 100.5 x105, 
and there were no records of collapse during the three years.

Sociobiology
An international journal on social insects

L Guimarães-Cestaro1, TS Maia2, R Martins2, MLTMF Alves3, IP Otsuk4, D Message5 EW Teixeira3

Article History

Edited by
Evandro N. Silva, UEFS, Brazil
Received                 02 January 2020
Initial acceptance  05 July 2020
Final acceptance   08 August 2020
Publication date   30 September 2020

Keywords 
Fungus, nosemosis, microsporidium.

Corresponding author
Lubiane Guimarães Cestaro
Av. Prof. Manoel César Ribeiro, 1920 
Santa Cecília, CP: 07, CEP: 12411010
Pindamonhangaba, São Paulo, Brasil.
E-Mail: lubi.guimaraes@gmail.com

Initially, the only etiological agent of this pathology 
in Apis mellifera bees was N. apis. However, the presence 
of N. ceranae (Higes et al., 2006; Huang et al., 2007) was 
also observed in the mid-2000s, initially in Apis cerana 
(Fries et al., 1996). It is believed, however, that N. ceranae 
began infecting A. mellifera bees a few decades ago, because 
analyses of historical samples have detected its presence in 
several places, such as Uruguay (Invernizzi et al., 2009), Brazil 
(Teixeira et al., 2013), Italy (Ferroglio et al., 2013), USA 
(Fell et al., 2015) and México (Guzman-Novoa et al., 2011; 
Guerreiro-Molina et al., 2016) in decades prior to its first 

1 - Postgraduate Program in Entomology, Department of Entomology, Federal University of Viçosa, Minas Gerais, Brazil 
2 - CNPq Scholarship (PIBIC): Undergraduate Student in Biological Sciences, UNITAU, Taubaté-SP, Brazil
3 - Laboratory Specialized in Honey Bee Health, Biological Institute/APTA/SAA, SP, Brazil
4 - Institute of Animal Science/APTA/SAA, SP, Brazil
5 - PVNS / CAPES Fellow, Graduate Program in Animal Science, UFERSA, Mossoró-RN, Brazil

RESEARCH ARTICLE - BEES

Nosema ceranae (Microsporidia: Nosematidae) Does Not Cause Collapse of Colonies of 
Africanized Apis mellifera (Hymenoptera: Apidae) in Tropical Climate



Sociobiology 67(3): 408-416 (September, 2020) 409

detection in bees of the genus Apis in 1996 (Fries et al., 1996).
Currently, the species N. ceranae is considered to be 

among the most prevalent infecting bees globally (Fries, 2010; 
Higes et al., 2010a; Gisder et al., 2010; Lecoq et al., 2016; 
Paxton et al., 2007; Higes et al., 2008; Emsen et al., 2016). N. 
ceranae can infect all members of the colony, be they workers, 
drones or queens (Alaux et al., 2011), including larvae (Eiri et 
al., 2015). This microsporidium infects the bees through the 
ingestion of spores from contaminated sources (pollen and 
water) and is eliminated in the feces (Fries et al., 1996).

The activities of cleaning and feeding in the colony bring 
new sources of infection (Fries, 2010; Higes et al., 2010b; 2013; 
Martin Hernandez et al., 2018). The spores germinate in the 
middle intestine, where the epithelial cells are infected, among 
other consequences causing the suppression of the immune 
system (Antúnez et al., 2009), energy stress (Mayack & Naug 
2009; Castelli et al., 2020), acceleration of age polyethism 
(Lecoq et al., 2016), with a consequent decrease in longevity, 
as well as reduction of honey production and pollination 
(Botías et al., 2013). Infection with this microsporidium has 
been associated with colony collapse disorder (CCD) in parts 
of Europe (Higes et al., 2009; Martín-Hernández et al., 2007), 
but not in central Europe (Gisder et al., 2010), South America 
(Invernizzi et al., 2009; Pires et al., 2006), and United States 
(Cox-Foster et al., 2007; Chen et al., 2008; Guzman-Novoa et 
al., 2016). According to Fries (2010), the impact of this parasite 
is different depending on the environment, and research has 
found conflicting virulence data, either for individual bees and 
colonies, presenting distinct seasonal patterns between areas.

In Brazil, N. ceranae is widely distributed throughout 
the country, with no pattern of infection intensity observed during 
the year (Teixeira et al., 2013; Pires et al., 2016). Their presence 
was first reported by Klee et al. (2007), but later studies have 
demonstrated their presence since the 1970s (Teixeira et al., 
2013), although no studies have so far evaluated the consequences 
of this infection in the long term. In tropical countries, there is 
little information about infections and seasonal patterns of N. 
ceranae (Guerrero-Molina et al., 2016; Fleites-Ayil et al., 
2018). Since detection of N. ceranae in A. mellifera coincided 
with the recent large-scale loss of bee colonies worldwide, 
data on pathology and management are of significant interest 
(Fries et al., 2013). Epidemiological assessments and studies 
conducted in this sense, in Brazil, may help to elucidate 
the causes of colony decline and sudden losses, since there 
is possible involvement of pathogens and parasites in this 

phenomenon (Teixeira et al., 2008a; 2008b; 2012; 2013; Santos 
et al., 2014; Schwarz et al., 2014), including N. ceranae.

Here we test two hypotheses, the first one, whether the 
climatic variables (temperature, air humidity and precipitation) 
influence the intensity of infection of the microsporidium 
Nosema spp. in Africanized honey bees (Apis mellifera), and 
the second, whether the local of hive installation (outdoor or 
roofed) influences the intensity of infection of these spores in 
Africanized honey bees.

Material and Methods

From August 2013 to August 2016, samples containing 
about thirty Africanized honey bees were weekly collected 
from 20 colonies in two apiaries of the Honey Bee Health 
Laboratory (LASA) of the Biology Institute of the São Paulo 
State Agribusiness Technology Agency (IB/APTA), in 
Pindamonhangaba, SP. Langstroth hives were installed at easels 
(height of 50 cm), ten in the open air (here called “outdoor apiary”) 
and ten under roof (3.2 m high) (here called “roofed apiary”).

The spore collections were performed according to 
Teixeira and Message (2010): the entrance to the hive´s was 
closed with a strip of common foam to allow the collection 
of honey bees arriving from the field. These honey bees were 
swept with a common brush (paint brush) 4 to 5 cm wide into 
a universal type plastic bottle, containing 70% alcohol. At 
least 30 bees were collected per hive. The counts of Nosema 
spp. were performed according to Cantwell (1970). 

For confirmation of the Nosema spp., composite samples 
were prepared from each beehive containing bees belonging to 
each weekly collection. Preparation of the samples for DNA 
extraction was done according to Teixeira et al. (2013) and 
for identification of the microsporidium species, the samples 
were submitted to duplex PCR reactions as described by 
Guimarães-Cestaro et al. (2016).

Data on temperature, air humidity and precipitation 
were obtained from the Polo do Vale do Paraíba meteorological 
station in Pindamonhangaba, SP, along with temperature and 
relative humidity obtained from a thermohygrometer installed 
in the covered apiary. In addition, pollen production data were 
obtained from September 2015 to August 2016 with pollen 
collectors of the intermediate type to evaluate the effect of 
this variable on the level of infection of the pathogen. 

Although meteorological data and pollen quantity were 
collected daily, a weekly average was performed for the 
assessments (Table 1 and 2).

Outdoor Apiary
 Spores Air humidity Precipitation Max. Temperature Min. Temperature

Autumn 360 30 33 36 36
Spring 380 36 26 38 38

Summer 390 26 27 39 39
Winter 390 26 39 39 39
Total 1520 118 125 152 152

Table 1. Sampling number (N value) for each studied variable on outdoor apiary: Spores (honey bee samples), air humidity, 
precipitation, maximum temperature, and minimum temperature.



L Guimarães-Cestaro et al. – N. ceranae Does Not Cause Collapse of Honey Bees in Tropical climate in open or roofed apiaries410

A completely randomized factorial experimental design 
was used (2 apiary types x 4 seasons), with 10 replicates 
(represented by hives). The data were analyzed through the 
MIXED procedure of the SAS (Statistical Analysis System) 
program (SAS Institute, 2001), to determine the matrix structure 
of variance and covariance. The significance level adopted 
for the analysis of variance was 5%. The apiary averages 
were compared by the F-test and the seasonal differences by 
the Tukey-Kramer test. Pearson and Spearman correlations 

between spore fluctuation and climatic variables (maximum 
and minimum temperature, humidity, and precipitation) and 
pollen production in each season of the year were calculated.

Results

All the analyzed samples presented positive results 
for the species Nosema ceranae, while Nosema apis was not 
detected (Fig 1).

Table 2. Sampling number (N value) for each studied variable on roofed apiary: Spores (honey bee samples), air humidity, 
precipitation, maximum temperature, and minimum temperature.

Covered Apiary
 Spores Air humidity Precipitation Max. Temperature Min. Temperature

Autumn 337 22 33 22 22
Spring 380 22 26 22 22

Summer 382 26 27 26 26
Winter 364 26 39 26 26
Total 1463 96 125 96 96

Season Outdoor Apiary Covered Apiary Mean

Spring 16.86±17.40aA 21.51±16.39aA 19.19±3.29
Summer 14.91±15.79aA 19.02±17.03aA 16.96±2.91
Autumn 14.01±14.18aA 11.09±11.70aB 12.55±2.06
Winter 14.34±15.99aA 18.21±15.03aA 16.38±2.74
Mean 15.03±1.28 17.46±4.47

†Means followed by different lowercase letters in the rows and upper case 
in the columns differ from each other by the Tukey-Kramer test (p ≤ 0.05).

Table 3. Intensity of natural infection of Nosema ceranae (average 
number of spores/bee x105) in hives located in open air and covered 
apiaries from August 2013 to August 2016 in relation to the seasons 
of the year.

Fig 1. Agarose gel (2%) showing duplex PCR products (Nosema apis/Nosema ceranae). M: Marker. 1-6: Samples infected 
with Nosema ceranae. C +: Positive control of Nosema apis (321bp) and Nosema ceranae (218bp). C-: Negative control.

Although outdoor hives had a lower mean number of 
spores than covered hives, N. ceranae infection intensities did 
not differ (p=0.0706) between the place of installation of the 
apiaries and the seasons, except for autumn in comparison 
with the other seasons in the colonies of the covered apiary 
(p<0.0001) (Table 3). 

The meteorological data were correlated with the 
fluctuation of the number of spores per bee (p<0.0001) only when 
considering season. In winter, the minimum temperature had a 

negative correlation with the number of spores in the outdoor 
apiary (Fig 2) and the humidity had a negative correlation with the 
number of spores in the covered apiary (Fig 3). Precipitation 
data had no influence on the intensity of infection (Fig 4).

The highest pollen production occurred in the summer 
and spring, when spore prevalence in bees was also high (Fig 5), 
without, however, presenting a significant difference (Table 4).

Season
Outdoor Apiary  
R value (P value)

Covered Apiary
R value (P value)

Spring -0,4301 (0,1726) -0,4348 (0,1376)
Summer -0,4447 (0,1705) -0,2662 (0,4289)
Autumn 0,1043 (0,7345) -0,1505 (0,6235)
Winter -0,4215 (0,1724) -0,3537 (0,2593)

Table 4. Pearson’s correlation coefficient between pollen production 
and spore fluctuation in each season evaluated. 

Discussion

The presence of Nosema ceranae and absence of 
Nosema apis corroborates the results obtained by Teixeira et 
al. (2013), Santos et al. (2014) and Guimarães-Cestaro et al. 
(2017a, 2017b), indicating possible supression of N. ceranae 



Sociobiology 67(3): 408-416 (September, 2020) 411

Fig 2. Intensity of natural infection of Nosema ceranae (mean number of spores/bee x105) and maximum and minimum 
temperatures in hives located in outdoor apiary and covered apiary from August 2013 to August 2016 in relation to seasons.

Fig 3. Intensity of natural infection of Nosema ceranae (mean number of spores/bee x105) and relative air humidity in hives 
located in open air apiary and covered apiary from August 2013 to August 2016 in relation to seasons.



L Guimarães-Cestaro et al. – N. ceranae Does Not Cause Collapse of Honey Bees in Tropical climate in open or roofed apiaries412

in the N. apis species in Africanized Apis mellifera bees in 
Brazil, as observed in honey bees in Europe (Klee et al., 2007; 
Paxton et al., 2007). However, it should be considered that 
reports of interactions between the two species of Nosema 
in bees are contradictory. Several authors have observed 
that in countries with hot summers and mild winters, there is 
predominance of N. ceranae (Higes et al., 2006; Klee et al., 

2007; Martín-Hernández et al., 2007), but in countries with 
cooler and longer winters, N. apis is predominant (Gisder et 
al., 2010; 2017). This can also be related to the presence of N. 
ceranae and the absence of N. apis in the samples analyzed 
in the present study and others performed in Brazil (Teixeira 
et al., 2013; Santos et al., 2014; Guimarães-Cestaro et al., 
2017a; 2017b). 

Fig 4. Intensity of natural infection of Nosema ceranae (mean number of spores/bee x105) and precipitation in hives 
located in outdoor apiary and covered apiary from August 2013 to August 2016 in relation to the seasons.

Fig 5. Intensity of natural infection of Nosema ceranae (average number of spores/bee x105) and pollen production in 
hives located in open air apiary and covered apiary from August 2015 to August 2016 in relation to the seasons of the year.



Sociobiology 67(3): 408-416 (September, 2020) 413

It is believed that cold weather is one of the limiting 
factors of N. ceranae distribution (Fries, 2010; Gisder et al., 
2010; Ozkirim et al., 2019), although environmental variables 
and interspecies competition are important elements to 
explain the differential prevalence of Nosema spp. in different 
climatic regions (Martín-Hernandez et al., 2018).

In our study, the climatic parameters did not influence 
(p<0.0001) the number of spores per bee, but considering 
the seasons, the largest number of spores was observed 
in the spring and the smallest in the autumn. These results 
can be explained by the development of the swarm in two 
different periods of nectariferous secretion that occur at 
the study site during the year. The first and most important 
occurs from February to mid-May and the second from mid-
July to September (Silva et al., 1995). During the main flow, 
the colonies had a higher population of bees, and with the 
end of the flowering period (which coincides with autumn), 
the population decreased, with a substantial decline in the 
queen’s posture, but without completely ceasing. With the 
development of a secondary flow, the colonies resumed their 
growth, with increased posture and population.

The lowest infection rate was observed when the 
colonies’ activity and population were reduced, due to lower 
temperatures and less availability of pollen, a product that is 
an important source of contamination by spores of Nosema 
spp. and other bee pathogens (Higes et al., 2008; Zheng et al., 
2014; Guimarães-Cestaro et al., 2016; Teixeira et al., 2018). At 
the end of winter and early spring, with the increase of comb 
cleaning for posture and consequent feeding of the larvae, there 
was higher availability of pollen (Fig 5), higher temperatures, 
in addition to greater wind intensity, which possibly facilitates 
the spread of spores through the air (Sulborska et al, 2019), 
increasing prevalence of this pathogen.

Different results (p<0.05) were obtained only for colonies 
of the covered apiary, which presented negative correlation 
for minimum winter temperature (14.98 ± 1.58 °C) (Fig 2), 
and for humidity in the open apiary (59.93 ± 10.91) (Fig 3). 
Similar data were obtained by Chen et al., (2012) in Taiwan, 
where infection by Nosema spp. had negative correlation with 
temperature, and higher spore counts were observed at mean 
temperature of 15 ºC. These results were associated with an 
increase in the bee population in the spring (Winston ,1987), 
and are also related to the fact that during this period, there is 
increased risk of the disease due to spore ingestion as the bees 
clean the combs and feed the larvae, while the presence of 
spores decreases in periods of low growth (Guerreiro-Molina 
et al., 2016). 

The type of apiary did not influence (p=0.0706) the 
number of spores per bee. Except during the autumn, in all 
seasons the hives in the roofed apiary tended to have higher 
infestation of N. ceranae, but without statistical difference.

The hives located in the open and roofed apiaries had, 
on average, 15.03 ± 1.28 x 105 and 17.46 ± 4.47x105 spores per 
bee, respectively, values close to those found by Santos et al. 
(2014) (16.5 ± 114 x 105 spores per bee) at this same location, 

and higher than those obtained in other municipalities of the state 
of São Paulo: 637 ± 36 x 103 (Santos et al 2014) and 1070 x 
103 (Guimarães-Cestaro et al 2017b).  The highest intensity 
of infection may be related to the weeklyfrequency and kind 
of management adopted (equalization of the population, comb 
exchanges between colonies, supplementation, among others).

In the current study, even considering the high infection 
rates in comparison to the other municipalities of the state 
of São Paulo (Santos et al., 2014; Guimarães-Cestaro et al., 
2017a; 2017b), no negative effects were observed that could 
be associated directly to infection by N. ceranae, and no 
collapse of colonies occurred during the three years analyzed. 
This article presents the first data on the infection intensity 
of N. ceranae during three consecutive years in Africanized 
bees in a tropical climate, allowing to infer that this pathogen 
does not cause a collapse in colonies frequently assisted of 
this honey bee hybrid in tropical areas.

Guerrero-Molina et al. (2016), concluded that Africanized 
bees infected with the pathogen suffer moderate effects when 
compared to European bees in temperate areas. Santos et al. 
(2014) and Guimarães-Cestaro et al. (2017b) verified the 
highest prevalence of N. ceranae in the autumn, but it is 
important to note that in these studies, the collections occurred 
only once in the season, unlike the current study, where bees 
were sampled were performed weekly. According to Teixeira 
et al. (2013) and Pires et al. (2016), in Brazil there is no 
pattern regarding the sporulation curve in different colonies 
and in geographically different places, as also mentioned by 
Fries et al. (2010) in the Northern Hemisphere.

The absence of colony collapses may be related with 
the constant and routinely management of apiaries, which 
made it possible to identify the early needs, for avoinding 
the substitution of queens, as consequence of absence or poor 
posture, as well as the needs of artificial suplementatation, 
timely offer of new wax foundations, adjustments in order to 
increase or decrease space according to population development, 
supplementation, among others. Studies carried in cages, with 
artificial infection by Nosema spp. have demonstrated the 
mortality of bees only a few days after infection (Higes et 
al., 2006; Paxton et al., 2007; Martín-Hernandez et al., 2011; 
Dussaubat et al., 2012). The technical management routinely 
adopted may have been crucial to allow the colonies to survive 
and to avoid losses reported in studies under artificial or natural 
conditions but not as often supervised and kept watch over.

Acknowledgments

We thank Carmen L. Monteiro and Vilma C.V. Takada 
for assistance in the analyses, and CNPq for specific funding 
(MAPA/CNPq, Process 2008-0 and APTA/PIBIC Program, 
E.W.T.).

Author Contribution Statement

LGC did the molecular analysis and helped to wrote the 
manuscript, RM and TMS executed sampling, helped with the 



L Guimarães-Cestaro et al. – N. ceranae Does Not Cause Collapse of Honey Bees in Tropical climate in open or roofed apiaries414

experimental analysis and the initial drafts of the manuscript, 
IPO performed the statistical analyses, DM helped to plan the 
work, EWT and MLTMFA were in charge of the assembly and 
maintenance of the hives and the monthly collection samples, 
EWT planed and coordinated the work, supervised all the 
steps of the investigation and wrote the manuscript, all authors 
collaborated in the revision of the final version of the manuscript.

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