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931 
Original Article 

Biosci. J., Uberlândia, v. 32, n. 4, p. 931-939, July/Aug. 2016 

ENDOREDUPLICATION IN FLORAL STRUCTURE, VEGETATIVE AND 

FRUITS OF RED PITAYA WITH WHITE PULP 
 

ENDORREDUPLICAÇÃO EM ESTRUTURA FLORAL, VEGETATIVA E FRUTOS DE 
PITAYA VERMELHA DE POLPA BRANCA 

 
Thatiane Padilha de MENEZES

1
; Leila Aparecida Salles PIO

2
; José Darlan RAMOS

3
; 

 Moacir PASQUAL
4
; Tesfahum Alemu SETOTAW

5 

1. Doutora em Agronomia, Universidade Federal de Lavras – UFLA, Lavras, MG, Brasil. thatiagro@yahoo.com.br; 2. Professora, 
Doutora em Agronomia, Universidade Federal de Lavras – UFLA, Lavras, MG, Brasil; 3. Professor, Doutor em Agronomia, 

Universidade Federal de Lavras – UFLA, Lavras, MG, Brasil; 4. Professor, Doutor em Agronomia, Universidade Federal de Lavras – 
UFLA, Lavras, MG, Brasil. mpasqual@dag.ufla.br; 5. Doutor em Agonomia, Universidade Federal de Lavras – UFLA, Lavras, MG, 

Brasil.  
 
ABSTRACT: Endoreduplication is the change of cellular cycle that result DNA duplication without cell 

division and could result endopolyploid cells. This phenomenon is common in plants and animals and considered as 
evaluative strategy. Although endoreduplication reported in various plant species, the information about these phenomena 
in red pitaya is rare. Therefore, this work was done with the objective of studying the endoreduplication in Hylocereus 
undatus Haw. using flow cytometry analysis. In this study were used the tissue from the flower structure, fruits, roots, 
cladode, and thorns of the pitaya plant.To determine the DNA content approximately 50 mg the sample of each treatment 
with Pisum sativum (the internal standard reference) were grind in plate of petri dishes contained 1 mL of cold Marie 
buffer to release the nucleus.The nuclear suspension was filtered through 50 µm  mesh. The nucleuses were colored with 
25 µL of 1 mg/L mL of propidium iodide. For each treatment, three samples of 10 thousand nucleuses were analyzed in 
cytometry Facscalibur (Becton Dickinson). The content of nuclear DNA (pg) was estimated as the ratio between 
fluorescence intensity of the G1 nucleus of the standard and the G1nucleus of the sample multiplied by the quantity of 
DNA of the internal reference. In conclusion, the endoreduplication occurred in all part of the plants analyzed except in the 
aculeus and the roots. The analysis evidenced different index of DNA content in the tissues analyzed being observed up to 
four different ploidy levels. The phenomena of endoreduplication occurs in all parts of the plant analyzed except in aculeus 
and roots.  

 
KEYWORDS: Flow cytometry. DNA content. Endopolyploidy. Hylocereus undatus Haw. 

 
INTRODUCTION  

 
Some decades ago, pitaya is cactaceae 

native to Tropical and subtropical America is 
unknown. But recently, itoccupied an increasing 
importance in exotic fruit market of Europe due to 
its exotism and organoleptic characteristics. The 
interest for the plant is recent and required more 
studies involving the agronomic, genetics and 
technology (MARQUES et al., 2011; BASTOS et 
al., 2006).  

It is known that during the development of 
some plants the normal cellular cycle can be 
substituted by the altered cellular cycle where did 
not occur mitoses (CHEVALIER et al., 2011). This 
altered cellular cycle is denominated as endocycle 
or endoreduplication which occur the DNA 
duplication without separation of chromosomes and 
cytokinesis (de VEYLDER et al., 2011). 

The endoreduplication can be initiated in 
various phases of plant development (de VEYLDER 
et al., 2011), thatcan result the variation of DNA 
content within the organism (COMAI, 2005). 

Consequently the edoreduplicated cells are 
produced and this is one form of somatic polyploidy 
(NAGL, 1976; D’AMATO, 1984). The increase in 
the ploidy level can increase the metabolism and 
genetic redundancy that improve the productivity 
and quality of the plant (COMAI, 2005). It also 
accelerates the metabolism and improves the 
physiological functionsof the plant (BARROW, 
2006).  

This phenomenon is found in abundance 
among angiosperms that grows in adverse 
environmental conditions suggested as an evaluative 
advantage (BARROW; MEISTER, 2003).It’s also 
reported in yeast and animals andbelieved to be the 
part of normal standard development or a response 
for physiological or genetic stimulus(EDGAR; 
ORR-WEAVER, 2001). It can also be associated 
with the increase in the size of the nucleus, cells, 
rate of metabolism, and cellular differentiation in 
variety of plants (SABELLI; LARKINS, 2008).  

The endoreduplication can be proved using 
the flow cytometry technique that measures the 
physical and/or chemical characteristics of a single 

Received: 10/02/16 
Accepted: 02/05/16 



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Endoreduplication in floral structure…  MENEZES, T. P. et al. 

Biosci. J., Uberlândia, v. 32, n. 4, p. 931-939, July/Aug. 2016 

particle. In this technique, the measurements are 
done when the number of particles in suspension 
passed individually through the focus of light 
generating pulses of reflected light and the 
fluorescence that are collected are converted in to 
pulses of electric current by optical sensor. This 
principle can measure for example the DNA content 
of the cell (DOLEZEL; BARTOS, 2005). 

The DNA content estimation has a number 
of application from basic research to plant breeding 
including estimating the genome size, evaluation of 
ploidy, detection of mixed ploidy and aneuploidy, 
evaluation of cellular cycle, study the chromosome 
elimination, cell separation, chromosome or 
organelles, among others (DOLEZEL; BARTOS, 
2005). 

Due to the importance of edoreduplication 
in plants and the absence of information about this 
phenomenon in pitaya fruit Brazilian , this work was 
done to study  the occurrence of these phenomena in 
various parts of red pitaya plant through flow 
cytometry analysis with the quantification of the 
DNA content of these structures. 

 
MATERIAL AND METHODS  

 
The experiment was realized in pitaya plant 

with four years old maintained by a structure type of 
trellis installed in experimental site of the 
Horticulture Research of the Department of 
Agriculture, Federal University of Lavras, Brazil. 
Pitaya plants were used with  five years of age in 3 x 
3 spacing, supported perpendicularly to the ground 
in eucalyptus stakes up to 1.80 m. 

The flow cytometer analysis was realized in 
floral structure of pitaya (sepals - the internal 
segment of perianth and petals - the external 
segment of perianth, stigma, anther, fillet, the bract 
of the pericarp, ovaries, ovary wall, ovules and 
pollen. The flowers completely opened with 32 cm 
length were used for analysis. In addition, tissues 
such as bract of epicarp, epicarp, mesocarp, 
endocarpoof the mature fruit (approximately 100 g) 
and immature (approximately 30 g), full seeds of 
mature fruits, thorns, cactus stems and roots were 
subjected for analysis. Three samples of different 
tissue taken from three different plants in each 
treatment were analyzed to verify the presence of 
endoreduplication.  

To determine the DNA, content 
approximately 50 mg of the tissue sample 
corresponding to each treatment together with 
Pisum sativum (the internal standard reference) were 
grinded in plate of petridish contain 1 mL of cold 
Marie buffer to release the nucleus. The nucleus 

suspension was aspirated through two gas chambers 
with the help of pipette of Pasteur and filtered using 
the 50 µm mesh. The nucleuses were colored with 
the addition of 25 µL of 1 mg mL-1 solution of 
propidium iodide for each sample. The samples 
were analyzed immediately after the preparation. 
For each sample, 10 thousand nucleuses were 
analyzed using the logarithmic scale. The analysis 
was realized using cytometer Facscalibur (Becton 
Dickinson) and the histogram is obtained with the 
software Cell Quest and analyzed statistically with 
the software WinMDI 2.8.  
 The nuclear DNA content (pg) of the plants 
was estimated using the ratio of fluorescence cense 
intensity of G1 nucleus of the standard reference (P. 
sativum) and the G1 nucleus of the sample 
multiplied by the DNA content of the standard 
reference (9.09 pg). The results obtained were 
submitted for analysis of variance (ANOVA) and 
the means were clustered using the Scott-Knott test, 
at 5% error probability by the software Sisvar 
(FERREIRA, 2011).  
 
RESULTS AND DISCUSSION  

 
The quantification of nuclear DNA through 

flow cytometer in a species is possible by 
comparing the pick formed by nucleus at G1 
interface stage of cellular cycle of the standard 
reference (the material where its DNA content 
known) to the G1 pick of the sample to be analyzed. 
In the present study the samples in majority of the 
treatments presented more than one pick. Due to this 
reason, pea (Pisum sativum) was used as a standard 
reference since its pick did not overlays to the picks 
produced by the samples.  

The coefficient of variation was below 2% 
for all the histograms that show high level of 
reliability of the results obtained in our study.  

Some flower tissues (stigma, ovules, ovary 
wall, pollen), mature fruits (bract of epicarp, and 
seeds) and immature (tissue of mesocarp, bract of 
epicarp, mesocarp, and endocarp) did not show 
picks in the histogram obtained therefore it is not 
possible to quantify the DNA of these materials. In 
contras in other treatments we obtained histograms 
with good quality.  

The treatments showed significant 
difference at 5 % probability. The analysis of flow 
cytometer indicated the existence of various level of 
ploidy in different structure of the plant that 
evidenced the phenomena of endoreduplication. 
However, in aculeus and roots the histograms 
presented only one value for the DNA content 
represented by one pick in the histogram. The rest of 



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Endoreduplication in floral structure…  MENEZES, T. P. et al. 

Biosci. J., Uberlândia, v. 32, n. 4, p. 931-939, July/Aug. 2016 

the treatments showed 2 to 4 picks in the histograms (Table 1).  
 

Table 1. Index of DNA in pg of different structures of red Pitaya.  
Treatment ID Peak 

1 
ID Peak 

2 
ID Peak 

3 
ID  

Peak 4 
Sepal – the external segment of perianth of the flower  7.92 a 14.10 f - - 
Petal – the internal segment of perianth of the flower  7.38 a 14.00 f 27.42 a 46.55 a 
Fillet  7.33 a 14.29 f 27.43 a - 
Anther 7.45 a 14.06 e 26.89 a - 
Stigmalobes 7.02 b 13.13 e - - 
Bract of epicarp of mature fruit  4.46 c 9.03 d 17.01 b 32.70 b 
Epicarp of mature fruit  4.03 d 8.60 c 15.85 c 31.07 c 
Epicarp of immature fruit  3.50 e 6,97 a 13.20 d 25,57 d 
Endocarp of mature fruit  4.05 d 8.07 b 15.94 c 32.24 b 
Cladode 7.22 b 13.77 e   
Aculeus 7.07 b - - - 
Roots  4.02 d - - - 

*The means followed by the same letters in the column belong in the same groups and did not differ among themselves by the Scott-
Knott test, at 5% error probability; ID: Index of DNA 

 
It was possible to observe that the treatment 

with more than one pick presented a DNA content 
value a multiple ofthe least (Table 1) that proved the 
occurrence of endoreduplication, that result the level 
of the DNA content to be 2C in the first pick, 4C in 
the second, 8C in the third, and 16C in the fourth. 
This can be due to the fact that the values of the 
DNA content in the referred picks are the multiple 
among them.   

According to Negron-Ortiz (2007), the 
phenomenon of endoreduplication is common in 
tissues of succulent plant and cactus. According to 
the author, the cactus under natural light presented 
very slow growth where endoreduplication is one of 
the mechanisms of adaptation of the plant to the 
extremely dray environmental condition and high 
temperature. 

The flow cytometer analysis of somatic 
embryo, buds and callus of cactus Copiapoa 
tenuissima Ritt, forma monstruosa, cultured in vitro 
presented the nucleus with various ploidy in various 
tissues studied (LEMA-RUMINSKA, 2011). The 
five ploidy level with DNA content 2C, 4C, 8C, 16C 
and 32C were found but in in vivo condition the 
maximum level was 16C. 

Probably, the endoreduplication was 
selected during the evolution for the benefit of the 
plant and organ development (CHEVALIER et al., 
2011). This phenomenon is important for the 
development process such as cell maintenance, 

response to physiological conditions like pest attack 
and on DNA damage (DE VEYLDER et al., 2011). 
The endoreduplication occurs typically in large 
cells, metabolically active or highly specialized, 
however can also be found in cells that are not 
corresponding to this condition (Lee et al., 2009).  

In plants, the occurrence of 
endoreduplication is common and documented in 
the endosperm of the cereal crops (SABELLI et al., 
2009), cotton fiber (Gossypium hirsutum) 
(WILKINS et al., 2000), tomato fruits 
(CHEVALIER et al., 2011), nitrogen fixing legumes 
(KONDOROSI; KONDOROSI, 2004). It is also 
reported in the endosperm and cotyledon of the 
seeds in development (LEE et al., 2009). In the 
hybrid Doritaeenopsis, the nucleus isolated from 
leave, somatic embryo, and root tips presented 
different level of endoreduplication (PARK et al., 
2010). 

Some factors are being associated with the 
variation of DNA content in plants are diversity of 
the species, temperature, altitude, seed weight, 
leaves, anatomical characteristics, generation time, 
and growth rate (KNIGHT et al., 2005).  
 In the present work, the histograms 
generated through the analysis of flow cytometer 
showed various picks in different plant structures. In 
Figures 1 and 2, it is possible to observe this 
variation in some plant parts of reproductive organs.

  
 



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Biosci. J., Uberlândia, v. 32, n. 4, p. 931-939, July/Aug. 2016 

 
Figure 1. Histogram of the flow cytometer for the quantification of DNA. A) Fillet. B) Stigma lobes C) 

Anthers of open flower of red pitaya (Hylocereus undatus Haw), with pea (Pisum sativum L.) used 
as standard reference.  

 

 
Figure 2. The histogram of flow cytometer for quantification of DNA.A) The external segment of perianth 

(sepal) B) internal segment of perianth (petal), of the open flower of red pitaya (Hylocereus 
undatusHaw), with pea (Pisum sativumL.) used as standard reference. 

 
According to Chen et al. (2011) 

endoreduplication can be occurred in flowers of 
some species and reported significant level of 
endopolyploidy in different flower structure of 
orchids. This phenomena was observed in flowers of 
cabbage during its development (KUDO; KIMURA, 
2001; KUDO; KIMURA, 2002) and in flowers of 

Portulaca grandiflora reported high level of 
endopolyploidy in different parts of the flower 
(MISHIBA; MII, 2000). In studies about the fruit 
size of mutant apple Gala, Malladi and Hirst (2010) 
before fructification observed the association of the 
size of carpel and floral tubes with the increase in 



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Biosci. J., Uberlândia, v. 32, n. 4, p. 931-939, July/Aug. 2016 

the cell numbers, large cell size and increase in 
ploidy through endoreduplication. 

In the analysis realized in open flowers of 
32 cm length the histogram generated from tissue of 
fillet, anther, and stigma lobes were presented in 
Figure 1. In the histograms of tissues of fillet and 
anther were observed three picks (1, 2 and 3) 
represent different level of ploidy (2C, 4C and 8C) 
and one pick of reference standard used to calculate 
the quantity of DNA of the samples. These results 
proved that these materials presented three distinct 
ploidy levels.  The analysis of the tissue from the 
stigma lobes evidenced two picks of the sample and 
one pick of the standard reference, suggested two 
level of ploidy 2C and 4C.  

In cactus and other succulent plants, 
endopolyploidy is related to the ecological 
mechanism important in situations with water deficit 
and high temperature (NEGRON-ORTIZ, 2007).  

 In histogram of Figure 2, it is possible to 
observe the internal tissue segment of perianth 
(sepal) presented two ploidy level and the external 
segment of perianth (petal) presented four distinct 
ploidy levels (2C,4C, 8C, and 16C).  
 Besides this, the quantity of DNA related to 
flower tissues vary from 7.02 to 7.92 pg which is 
very high in relation to other tissue analyzed and 
this tendency was maintained in the subsequent 
picks.  
 Some tissues such as stigma, ovules, ovary 
wall, pollen, bract of epicarp of the mature and 
immature fruits, mesocarp tissue, bract of epicarp, 
mesocarp and endocarpof immature fruits and seeds 
are not produced pick in the histogram. Figure 3 
illustrated the analysis of tissues from epicarp bracts 
where the pick observed in the histogram is in 
relation to the internal reference standard. 

 
 

 
Figure 3. The histogram of flow cytometer for DNA quantification for sample tissue of bracts of the pericarp 

of the open flower of red pitay a(Hylocereus undatus Haw.) with pea (Pisum sativumL.)used as 
standard reference.  

 
There are various hypotheses for not 

presenting the pick in the histogram in these 
materials; one of them is the formation of secondary 
metabolites in the tissue that interfere in the 
analysis. The extraction buffer may not be 
appropriate for the different tissues that form the 
treatments. Besides this, the presence of proper 
mucilage of the cactus can be influenced. The tissue 
of mesocarp of the fruits possess intense purple 
coloring that indicate the presence of anthocyanin. 
This pigment can also influence in the quality of the 
samples.  

 The cytometer analysis of the mature fruit 
(Figure 4) evidenced four distinct level of ploidy for 
epicarp, bract and endocarp, suggesting high index 
of endoreduplication. These four different levels of 
ploidy were verified still for the tissues of epicarp of 
the immature fruits and petals. From the analysis of 
the fruits, it is possible to verify the index of DNA 
are much lower than other tissues and vary from 3.5 
to 4.46 pg in the first pick following the tendency of 
the subsequent picks (Table 1).  

 



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Endoreduplication in floral structure…  MENEZES, T. P. et al. 

Biosci. J., Uberlândia, v. 32, n. 4, p. 931-939, July/Aug. 2016 

 
Figure 4. The histogram of flow cytometer for DNA quantification.A) Epicarp of the mature fruit. B) Bract of 

mature fruit. C) Endocarp of mature fruit of red pitaya (Hylocereus undatus Haw.), with pea (Pisum 
sativum L.) used as standard reference.  

 
 
In recent studies, Bourdon et al. (2010) reported 
endoreduplication occurs in fleshy fruits that 
developed rapidly in 13 weeks with three to eight 
cycles of endocyclespecially in Solanaceae  
Cucurbitaceae. According to Marques et al. (2011), 
the complete maturation of the fruit of pitaya occurs 
30 to 40 days after the flower opens. This fast 
development of the fruits presented a correlation 
with the phenomena of endoreduplication. 
 In tomato, the final cell size within pericarp 
of the fruit was correlated with the level of 
endoreduplication (CHENICLET et al., 2005). This 
phenomena appears not essential for the 
development of the fruit in apple (HARADA et al., 

2005), however, the endoreduplication was reported 
in apple variety Grande Gala during the flowering 
and initial growth of the fruit (MALLADI; HIRST, 
2010). 

The analysis of tissues of vegetative 
structures of red pitaya (cladode, aculeus and root) 
are presented in Figure 5. From the histogram it is 
possible to observe the phenomena 
endoreduplication occurred only in cladode with one 
pick representing possibly with diploid cells and 
other by tetraploid cells. In the coleus and roots 
endoreduplication was not observed since the 
samples showed only one level of ploidy (2C).

  

 
Figure 5. The histogram of flow cytometer for DNA quantification.A) Root. B) Cladode. C) Aculeus of red 

pitaya plant (Hylocerus undatus Haw.), with pea (Pisum sativumL.) used as standard reference.  



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Endoreduplication in floral structure…  MENEZES, T. P. et al. 

Biosci. J., Uberlândia, v. 32, n. 4, p. 931-939, July/Aug. 2016 

Frequently the endoreduplication occurred 
during the cellular differentiation that is highly 
specialized in its morphology such as cladode that is 
the modification of stalk. However, in the present 
work this phenomenon was occurred in various 
tissues. Although it is common in plants, the 
significance of endoreduplication still not well 
clarified.  New studies are necessary to enlighten the 
transition of mitotic cellular cycle to cycle of 
endoreduplication in pitaya. It is possibly genetics 
and molecular mechanisms are involved in the 
phenomena of endoreduplication in this species.  
 
CONCLUSIONS  

 
The phenomena of endoreduplication occurs 

in all parts of the plant analyzed except in aculeus 
and roots.  

The analysis proved different index of DNA 
content in the tissues and observed four level of 
ploidy. 

The index of DNA is high in the floral 
structure and cladode. The aculeus, in the parts of 
fruits and roots was minimum.  
 
ACKNOWLEDGMENT  

 
We thanks the CNPq (Conselho Nacional de 

Desenvolvimento Científico e Tecnológico) and 
Capes (Coordenação de Aperfeiçoamento de 
Pessoal de Nível Superior) for its financial support 
to realize this work.  

 

 
 

RESUMO: A endorreduplicação é uma alteração do ciclo celular, ocorrendo a replicação do DNA sem a divisão 
celular, podendo resultar em células endopoliploides. É um fenômeno comum em plantas e animais, sendo considerada 
uma estratégia evolutiva. Embora a endorreduplicação seja relatada em diversas espécies de plantas, as informações sobre 
este fenomeno em pitaia vermelha são escassas. Assim, objetivou-se com este trabalho estudar a endorreduplicação em 
Hylocereus undatus Haw. pela técnica de citometria de fluxo. Foram analisados tecidos de estruturas florais, de frutos, 
raiz, cladódio e acúleos de plantas de pitaia. Para a determinação do conteúdo de DNA, aproximadamente 50 mg de 
amostra de cada tratamento,  juntamente com Pisum sativum (padrão de referência interno) foram triturados em placa de 
Petri contendo 1 mL de tampão Marie gelado para a liberação dos núcleos. A suspensão de núcleos foi filtrada através de 
malha de 50 µm. Os núcleos foram corados com 25 µL de solução de 1 mg/1 mL de iodeto de propídeo para cada amostra. 
Para cada tratamento, três amostras de 10 mil núcleos foram analisadas em citômetro Facscalibur (Becton Dickinson).  O 
conteúdo de DNA nuclear (pg) foi estimado utilizando-se a razão entre as intensidades de fluorescência dos núcleos G1 do 
padrão de referência e dos núcleos G1 da amostra, multiplicando-se esta razão pela quantidade de DNA do padrão de 
referência. Conclui-se que a endorreduplicação ocorre em todas as partes da planta analisada, exceto no acúleo e na raiz. 
As análises evidenciam diferentes índices de conteúdo de DNA nos tecidos, sendo observados até quatro diferentes níveis 
de ploidia. O fenômeno da endorreduplicação ocorreu em todas as partes da planta analisadas, exceto nos acúleos e raízes. 

 
PALAVRAS-CHAVE: Citometria de fluxo. Conteúdo de DNA. Endopoliploidia. Hylocereus undatus Haw. 

 
 
REFERENCES 
 
BASTOS, D. C.; PIO, R.; SCARPARE FILHO, J. A.; LIBARDI, M. N.; ALMEIDA, L. F. P. de, GALUCHI, 
T. P. D.; BAKKER, S. T. Propagação de pitaya vermelha por estaquia. Ciência & Agrotecnologia, Lavras, v. 
30, p. 1106-1109, 2006. 
 
BAROW, M. Endopolyploidy in seed plants. BioEssays, Massachusetts, v. 28, p. 271-281, 2006. 
http://dx.doi.org/10.1002/bies.20371 
 
BAROW M.; MEISTER, A. Endopolyploidy in seed plants is differently correlated to systematics, organ, life 
strategy and genome size. Plant, Cell and Environment, Oxford, v. 26, p.571-584, 2003. 
http://dx.doi.org/10.1046/j.1365-3040.2003.00988.x 
 
BOURDON M, FRANGNE, N.; MATHIEU-RIVET, E.; NAFATI, M.; CHENICLET, C.; RENAUDIN, J. P.; 
CHEVALIER, C. Endoreduplication and growth of fleshy fruits. In: ‘Progress in botany 71’. (Eds U Lüttge, W 
Beyschlag, B Büdel, D Francis) p. 101-132. (Springer: Berlin). 2010. http://dx.doi.org/10.1007/978-3-642-
02167-1_4 



938 
Endoreduplication in floral structure…  MENEZES, T. P. et al. 

Biosci. J., Uberlândia, v. 32, n. 4, p. 931-939, July/Aug. 2016 

 
CHEVALIER, C.; NAFATI, M.; MATHIEU-RIVET, E.; BOURDON, M.; FRANGNE, N.; CHENICLET, C.; 
RENAUDIN, J. P.; GÉVAUDANT, F.; HERNOULD, M. Elucidating the functional role of endoreduplication 
in tomato fruit development. Annals of Botany, Oxford, v. 107, p.1159-1169, 2011. 
http://dx.doi.org/10.1093/aob/mcq257 
 
CHEN, W-H.; TANG,C-Y.; LIN,T-Y.; WENG,Y-C.; KAO,Y-L. Changes in the endopolyploidy pattern of 
different tissues in diploid and tetraploid Phalaenopsis saphrodite subsp. formosana (Orchidaceae).Plant 
Science, Ireland, v. 181, p.31-38, 2011. http://dx.doi.org/10.1016/j.plantsci.2011.03.006 
 
CHENICLET, C.; RONG, W. Y.; CAUSSE, M.; FRANGNE, N.; BOLLING, L.; CARDE J. P.; RENAUDIN, 
J. P. Cell expansion and endoreduplication show a large genetic variability in pericarp and contribute strongly 
to tomato fruit growth. Plant Physiology, v. 139, p.1984-1994, 2005. http://dx.doi.org/10.1104/pp.105.068767 
COMAI, L. The advantages and disadvantages of being polyploid. Nature Reviews Genetics. v. 6, p. 836–846, 
2005. http://dx.doi.org/10.1038/nrg1711 
 
DE VEYLDER, L.; LARKIN, J. C.; SCHNITTGER, A. Molecular control and function of endoreplication in 
development and physiology. Trends in Plant Science. Oxford, v. 16, p. 624–634, 2011. 
 
D’AMATO, F. Role of polyploidy in reproductive organs and tissues. In: Johri, B.M. (Ed.), Embryology of 
Angiosperms. Springer-Verlag, New York, p. 523e 566, 1984. http://dx.doi.org/10.1007/978-3-642-69302-
1_11 
 
DOLEZEL, J.; BARTOS, J. Plant DNA flow citometria and estimation of nuclear genome size. Annals of 
Botany, London, v. 95, p. 99-110, 2005. http://dx.doi.org/10.1093/aob/mci005 
 
EDGAR, B. A.; ORR-WEAVER, T. L. Endoreplication cell cycles: more for less. Cell, v. 105, p. 297-306, 
2001. http://dx.doi.org/10.1016/S0092-8674(01)00334-8 
 
FERREIRA, D. F. Sisvar: a computer statistical analysis system. Ciência e Agrotecnologia,  v. 35, n. 6, 
pp.1039-1042. 2011. 
 
HARADA, T.; KURAHASHI, W.; YANAI, M.; WAKASA,Y.; SATOH, T. Involvement of cell proliferation 
and cell enlargement in increasing the fruit size of Malus species.ScientiaHorticulturae, Amsterdam, v. 105, 
p. 447–456, 2005. http://dx.doi.org/10.1016/j.scienta.2005.02.006 
 
KNIGHT, C. A, MOLINARI, N. A, PETROV, D. A. 2005. The large genome constraint hypothesis: evolution, 
ecology and phenotype. Annals of Botany, Oxford, v. 95, p. 177–190, 2005. 
 
KUDO, N., KIMURA,Y. Flow cytometric evidence for endopolyploidy in seedlings of some Brassica species, 
Theoretical and Applied Genetics, Heidelberg, v. 102. p. 104-110, 2001. 
http://dx.doi.org/10.1007/s001220051624 
 
KUDO, N.; KIMURA, Y. Nuclear DNA endoreduplication during petal development in cabbage: relationship 
between ploidy levels and cell size. Journal of Experimental Botany, v. 53, p. 1017-1023, 2002. 
http://dx.doi.org/10.1093/jexbot/53.371.1017 
 
KONDOROSI, E.; KONDOROSI, A. Endoreduplication and activation of the anaphase-promoting complex 
during symbiotic cell development. FEBS Lett.567, 152–157, 2004. 
http://dx.doi.org/10.1016/j.febslet.2004.04.075 
 
LEMA-RUMINSKA, J. Flow cytometric analysis of somatic embryos, shoots, and calli of the cactus 
CopiapoatenuissimaRitt.formamonstruosa. Plant Cell Tissue OrganCulture, Urbana, v. 106, p. 531–535, 
2011. http://dx.doi.org/10.1007/s11240-011-9941-7 
 



939 
Endoreduplication in floral structure…  MENEZES, T. P. et al. 

Biosci. J., Uberlândia, v. 32, n. 4, p. 931-939, July/Aug. 2016 

LEE, H. O.; DAVIDSON, J. M.; DURONIO, R. J. Endoreplication: polyploidy with purpose. Genes 
&Devlopment. v. 23, p. 2461–2477, 2009. http://dx.doi.org/10.1101/gad.1829209 
 
MARQUES, V. B.; AMATO, R. A.; RAMOS, J. D.; ARAUJO, N. A. de, SILVA, F. O. dos. R. Fenologia 
reprodutiva de pitaia vermelha no município de Lavras, MG. Ciência Rural. Santa Maria, v. 41, p. 984-987, 
2011. http://dx.doi.org/10.1590/S0103-84782011005000071 
 
MALLADI, A.; HISRT, P. Increase in fruit size of a spontaneous mutant of ‘Gala’ apple (Malus x domestica 
Borkh.) is facilitated by altered cell production and enhanced cell size. Journal of Experimental Botany, v. 
61, p. 3003–3013, 2010. http://dx.doi.org/10.1093/jxb/erq134 
 
MISHIBA, K. I.; MII, M. Polysomaty analysis in diploid and tetraploidPortulacagrandiflora. Plant Science. 
Ireland, v. 156, p. 213–219, 2000. 
NAGL, W. DNA endoreduplication and polyteny understood as evolutionary strategies. Nature. United States, 
v. 261, p. 614–615, 1976. http://dx.doi.org/10.1038/261614a0 
 
NEGRON-ORTIZ, V. Chromosome numbers, nuclear DNA content, and polyploidy in Consolea (Cactaceaae), 
an endemic cactus of the Caribbean Islands. American Journal of Botany, Saint Louis, v. 94, n. 8 p. 1360–
1370, 2007. http://dx.doi.org/10.3732/ajb.94.8.1360 
 
PARK, S-Y.; YEUNG, E. C., PAEK, K-Y. Endoreduplication in Phalaenopsis is affected by light quality from 
light-emitting diodes during somatic embryogenesis. Plant Biotechnology Reports, v. 4, p. 303–309, 2010. 
http://dx.doi.org/10.1007/s11816-010-0148-x 
 
SABELLI, P. A.; LARKINS, B. A. The contribution of cell cycle regulation to endosperm development.Sexual 
Plant Reproduction, Oklahoma, v. 22, p. 207-219, 2009. http://dx.doi.org/10.1007/s00497-009-0105-4 
 
SABELLI, P. A., LARKINS, B. A. The endoreduplication cell cycle: regulation and function. In: Verma, D. P. 
S., Hong, Z. (Eds.), Cell Division Control in Plants. Springer-Verlag, Berlin-Heidelberg, p. 75e100, 2008. 
 
WILKINS, T. A.; RAJASEKARAN, K.; ANDERSON, M. D. Cotton biotechnology.Critical Reviews in Plant 
Sciences, v. 19, p. 511–550, 2000. http://dx.doi.org/10.1016/S0735-2689(01)80007-1