










































Microsoft Word - 19-Agra_30293.doc


1771 
Original Article 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1771-1777, Nov./Dec. 2015 

FLORAL INDUCTION, PRODUCTION AND SEED QUALITY OF PARSLEY 
CULTIVARS AS INFLUENCED BY PLANTS VERNALIZATION PERIODS 

 
INDUÇÃO FLORAL, PRODUÇÃO E QUALIDADE DE SEMENTES DE 

CULTIVARES DE SALSA EM FUNÇÃO DE PERÍODOS DE VERNALIZAÇÃO DAS 
PLANTAS 

 
Cibele Chalita MARTINS

1
; Carla Gomes MACHADO

2
; Mauricio Feis Ganz SANCHES

3
; 

Juliana Faria dos SANTOS
3
; Roberval Daiton VIEIRA

1
 

1. Engenheiro agrônomo, Professor, Doutor, Departamento de Produção Vegetal, Faculdade de Ciências Agrárias e Veterinárias – 
FCAV, Universidade Estadual Paulista - UNESP, Jaboticabal, SP, Brasil. cibele@fcav.unesp.br; 2. Engenheiro agrônomo, Professor, 

Doutor, Universidade Federal de Goiás, Campus Jatobá, Jataí, GO, Brasil; 3. Engenheiro agrônomo, Discente do Curso de Pós-
graduação em Agronomia, Produção Vegetal, Faculdade de Ciências Agrárias e Veterinárias – FCAV, Universidade Estadual Paulista - 

UNESP, Jaboticabal, SP, Brasil. 

 
ABSTRACT: In the production of parsley (Petroselinum crispum) seeds is recommended the cultivation in 

locations of low temperatures to permit the emission of floral stalk. The study aimed to verify the effect of vernalization on 
floral induction, production and quality of parsley seeds. Ten plants of three cultivars (Caipira, Chacareira and Lisa Grande 
Portuguesa (O. Enke)) grown in pots for six months were submitted to vernalization at 5 °C for 0, 15, 30 and 45 days. 
After treatment, the plants were transferred to greenhouse and evaluated for period and flowering percentage, seed yield 
per plant and seed quality. The seed quality was evaluated by weight of a thousand seeds, germination (percentages of 
normal and abnormal seedlings, dormant and dead seeds), first count of germination, accelerated aging, dormancy after 
accelerated aging, seedling emergence in the field and seed water content before and after accelerated aging. It was 
concluded that the vernalization does not promotes floral induction and production of parsley seeds. For Lisa Grande 
Portuguesa (O. Enke) cultivar, the vernalization of the plant for 30 days enables the production of seed with high 
germination and vigor. Parsley seeds dormancy can be caused by plants vernalization periods between 30 and 45 days 
depending on the cultivar, followed by the exposure of the seeds to the conditions of high temperature and relative 
humidity of the air (41 °C/100%, UR/72 h). 
 

KEYWORDS: Petroselinum crispum. Flowering. Dormancy. Vigor. Vegetables. 
 
INTRODUCTION  

 
Parsley [Petroselinum crispum (Mill.) 

Nyman ex A.W. Hill] is a biennial herbaceous plant 
that can be also grown as an annual crop. It is 
originated from Europe and cultivated in Brazil for 
more than 300 years. It is one of the most popular 
plants in the world gastronomy, its leaves being 
consumed either fresh or dehydrated. Its culm is 
erect, reaching a height between 15 and 30 cm.  
Parsley regenerates easily and consequently, enables 
various harvest during the year (FILGUEIRA, 
2003).  

Parsley plants grow better under warm 
temperatures and are damaged by extreme 
temperatures, both high and low. It can be sown 
during the whole year in the South of Brazil, in São 
Paulo and Minas Gerais states. In other Brazilian 
states and regions, sowing should take place 
between February and November. For the 
production of seeds, the recommendation is to grow 
the plants in low altitude and low temperature sites 
to induce the emission of the flower rachis 
(FILGUEIRA, 2003; TRINCA, 2007). 

The floral induction process consists of the 
transformation of the vegetative bud into 
reproductive or floral bud under a stimulus from the 
environment; if this stimulus does not take place, 
there will be no fruit and seed production 
(NASCIMENTO, 2005; MARCOS-FILHO, 2005). 
But, to respond to the stimulus, the biennial species 
should surpass the juvenile period and exhibit a 
certain vegetative growth which is genotype 
dependent since the buds and meristem tissue are 
the receptors of those stimuli (MARCOS-FILHO, 
2005; ALESSANDRO; GALMARINI, 2007).  

Some vegetable crops demand low 
temperatures for the induction of flowering and, 
consequently, the production of seeds, such as are 
the cases of onion, carrot, and cauli-flower. These 
are conditions which can be artificially provided to 
the plants in cold chambers in a process named 
vernalization. 

The temperature range that brings about 
floral induction depends on genetics characteristics 
and, for most of the vegetable crops, it is between 5 
and 10 °C (FILGUEIRA, 2003; MARCOS-FILHO, 
2005; ALESSANDRO; GALMARINI, 2007; 

Received: 19/05/15 
Accepted: 10/08/15 



1772 
Floral induction, production…  MARTINS, C. C. et al. 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1771-1777, Nov./Dec. 2015 

VERDIAL et al., 2007). But no research 
information concerned to the effects of vernalization 
on parsley seed production were found. 

So, the objective of this research was to 
verify the effects of plant vernalization on the floral 
induction, production and quality of parsley seeds. 
 
MATERIAL AND METHODS 

 
The experiment was carried out on the São 

Manuel Experimental Farm and in the Seed 
Analysis Laboratory of the Faculty of Agronomic 
Sciences at UNESP, São Paulo State, Brazil 
(22°44'50" S, 48°34'00" W; altitude 765 m; climate 
Cwa, hot temperature in general, with rains in the 

summer and drought in the winter (CUNHA; 
MARTINS, 2009)). Monthly temperatures 
minimum, maximum and mean during the 
experiment are shown in Table 1. 

Parsley seeds of the cultivars Caipira, 
Chacareira, and Lisa Grande Portuguesa (O. Enke) 
were sown in September of 2008 in 1.5 L vases 
which were filled with a mixture in equal 
proportions of soil, sand, and Plantmax and the 
plantlets grown under greenhouse conditions. Plants 
remained for six months in these conditions so that 
there was sufficient vegetative growth to become 
sensitive to vernalization process (SAMUOLIENĖ 
et al., 2009). 

 
Table 1. Monthly minimum, maximum and mean temperatures (°C) measured during the months of the 

experiment. São Manuel, São Paulo State, Brazil. 

Month and year 
Temperature (°C) 

Minimum Maximum Mean 

September 2008 13.8 26.5 20.1 
October 2008 14.2 27.8 21.0 
November 2008 17.3 30.4 23.9 
December 2008 16.9 29.4 22.9 
January 2009 15.1 29.1 21.9 
February 2009 17.4 29.8 23.4 
March 2009 16.7 29.4 22.7 
April 2009 14.1 27.8 20.9 
May 2009 12.2 25.7 19.0 
June 2009   8.7 22.9 15.8 
July 2009 10.9 22.9 16.9 
August 2009 11.4 26.1 18.8 
September 2009 12.7 25.2 18.9 

 
After this period (end of March of 2009), 

for each cultivar and at 15 day intervals, 10 vases 
with one plant per vase were transferred to a cold 
chamber (5 °C) making a total of 90 vases with a 
maximum permanence period of 45 days. So, the 
treatments analyzed in this experiment were four 
vernalization periods (0, 15, 30, and 45 days) and 
three cultivars (Caipira, Chacareira and Lisa Grande 
Portuguesa). At the end of the vernalization 
procedure (May 15th, 2009), all the vases were 
transferred to a greenhouse, for the following 
evaluations: 

 
Flowering and seed production 

The percentage of plants emitting floral 
rachises and the moment it took place. Among the 
plants submitted to vernalization, eight were 
randomly taken and their seed production evaluated. 
Seeds were harvested, cleaned, weighed and the 
results expressed in g of seeds per plant. 

In the laboratory, the seeds of each 
treatment were homogenized and submitted to the 
following determinations and tests: 

 
One thousand seeds weight 

It was determined with basis on eight 100 
seed samples randomly taken from the seeds. The 
samples were weighed and the results expressed in g 
(BRASIL, 2009). 

 
Germination test  

This test was carried out with four 50 seed 
samples. The seeds were spread on top of two filter 
paper which were wet with an amount of water 
equal to 2.5 times the weight of the paper in 11 × 11 
× 3.5 cm transparent plastic boxes. The boxes were 
placed in a germination chamber at 20 °C with 
counting taking place 10 and 28 days after sowing. 
Percentage of normal and abnormal seedlings were 
determined (BRASIL, 2009). 



1773 
Floral induction, production…  MARTINS, C. C. et al. 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1771-1777, Nov./Dec. 2015 

First count of germination 
This was the percentage of normal seedlings 

counted on the 10th day after the beginning of the 
germination test (BRASIL, 2009). 

 
Accelerated aging test 

We carried out with 2 g of seeds spread on 
top of a screen in a transparent plastic box (11 × 11 
× 3.5 cm)  to which 40 mL of water was added and 
kept at 41 °C (100%) for 72 hours (RODO et al., 
2000). Then, the seeds were submitted to the 
standard germination test and the resulting seedlings 
evaluated on the 10th day. 

 
Tetrazolium test 

It was executed after germination and 
accelerated aging tests, using the remaining seeds 
from each one. Seeds were longitudinally and 
medially sectioned through the embryo. One of the 
halves of each seed was immersed in a 0.1% 
tetrazolium solution and kept in a dark chamber at 
35 °C for a period of 60 minutes. After that period, 
the seeds were washed and the evaluation made 
immediately after and the seeds were classified as 
either dormant (after germination and accelerated 
aging tests) or dead (after germination test) 
(ANDRADE et al., 1996). 

 
Seed water content  

Seed water content was determined before 
and after the seeds were artificially aged using two 
samples per lot by the oven method with high 
temperature for a short period of exposition, that is, 
130 ± 3 °C/1 hour (BRASIL, 2009).  

 
Seedling emergence in the field 

Four replications of 100 seeds were sown in 
0.8 m long and 1.0 cm deep rows. The distance 
between rows was of 10 cm. During the test 
duration, when necessary, irrigations were made at 
the end of the day. Seedling counts were made 40 
days after sowing with the results being presented in 
percentage (VIEIRA and CARVALHO, 1994).  

 
Statistical procedures 

A completely random design with eight 
repetitions for seed production and 1000 seeds 
weight and four repetitions for the other 
determinations was adopted. The treatments were 
arranged in a 4 × 3 factorial scheme in which 4 were 
the vernalization periods and 3 the cultivars. Means 
were compared with the Tukey test at the level of 
5% of probability.   
 
 

RESULTS AND DISCUSSION  
 
The beginning of the floral rachis emission 

occurred one year after sowing (approximately four 
months after vernalization) and 90 to 100% of the 
plants flowered, regardless of cultivar and 
vernalization treatments. Alessandro and Galmarini 
(2007) and Verdial et al. (2007) reported results 
with carrot and strawberry in which floral induction 
was caused by vernalization depending on cultivar 
and time of exposition to low temperatures.  

For parsley, probably the flowering stimulus 
may be caused by other factors such as, perhaps, the 
photoperiod or this factor in association with low 
temperatures such as reported for some carrot and 
lettuce cultivars and beetroot (NASCIMENTO, 
2005). At the time of the year in which flower 
rachises started to be emitted, day length in São 
Manuel was of approximately 11 hours and 50 
minutes and temperature conditions are in Table 1.  

Seed production by the evaluated cultivars 
was not affected by vernalization with the exception 
of the Caipira cultivar which yielded less than the 
Chacareira cultivar when vernalization period was 
of 45 days (Table 2).  

Vernalization had no effect on the 
translocation and accumulation of seed reserves and 
thus on seed mass as shown by the determination of 
the mass of 1,000 seeds. Lisa Grande Portuguesa 
parsley produced seeds lighter than those of the 
Caipira but similar to those of the Chacareira 
cultivar. Chacareira seeds are of intermediate 
weight, not different from that of the Caipira 
cultivar under some environmental conditions, such 
as when vernalization is not applied or when this 
treatment lasts for 30 days (Table 2). In this way, 
seeds of different cultivars exhibited different 
masses since this is a genetically determined 
characteristic (BRASIL, 2009). Same behavior was 
verified for carrot seeds progenies, species 
belonging to the family Apiaceae, as parsley 
(MARTINS et al., 2014). 

The one thousand seed mass is usually used 
to calculate sowing density and the number of seeds 
per package and since it is genetically determined, 
that is, it depends on the cultivar, its information is 
not demanded by the Ministry of Agriculture for the 
commerce of Vegetable seed lots (BRASIL, 1986; 
BRASIL, 2009).  

Taking in consideration that seed production 
per plant was similar but the weight of the Lisa 
Grande Portuguesa cultivar seeds was lower, it may 
concluded that that cultivar  produces a larger 
number of seeds, which are lighter than the seeds of 
the other cultivars.  



1774 
Floral induction, production…  MARTINS, C. C. et al. 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1771-1777, Nov./Dec. 2015 

Table 2. Seed production, one thousand seed weight, first count of germination test, germination, abnormal 
seedlings, dormant and dead seeds, accelerated aging test, dormancy after accelerated aging, seedling 
emergence in the field, seed initial and after accelerated aging moisture content of parsley seeds of the 
cultivars Lisa Grande Portuguesa, Caipira, and Chacareira produced by plants vernalized for 0, 15, 30, 
and 45 days at a temperature of 5 °C.  São Manuel, state of São Paulo, Brazil. 2013. 

Vernalization 
Lisa Grande 
Portuguesa 

Caipira Chacareira  
Lisa Grande 
Portuguesa 

Caipira Chacareira 

(days) Seed production (g/plants)  1,000 seeds mass (g) 

0 69.48 A  a 85.90 Aa 82.40 Aa  1.50 Ba 1.97 Aa 1.73 ABa 
15 82.00 A  a 71.08 Aa 69.58 Aa  1.49 Ba 1.96 Aa 1.64 B   a 
30 78.53 A  a 83.35 Aa 87.50 Aa  1.52 Ba 1.93 Aa 1.75 ABa 
45 77.80 ABa 69.29 Ba 98.25 Aa 

 
1.54 Ba 1.95 Aa 1.69 B   a 

CV%  28.10   11.85  
 First count of germination (%) 

 

Germination (%) 

0 46.5 Bc 91.5 Aa 86.5 Aa 51.0 Bc 93.0 Aa 88.0 Aa 
15 51.0 Bbc 83.0 Aa 88.0 Aa  60.0 Bb 84.0 Ab 90.5 Aa 
30 61.5 Bab 93.0 Aa 91.0 Aa  89.0 Aa 96.0 Aa 95.5 Aa 
45 63.5 Ba 86.0 Aa 90.5 Aa 

 
66.0 Bb 88.0 Aab 91.5 Aa 

CV%  8.04   5.53  
 Abnormal seedlings (%)  Dormant (%) 

0 0.0 1.5 1.5  1.0 Ba 1.5 Bb 6.0 Aa 
15 0.0 0.0 1.5  0.0 Aa 1.5 Ab 1.5 Aab 
30 1.5 1.0 0.5  0.0 Aa 2.5 Aab 1.5 Aab 
45 0.0 0.0 1.0 

 
3.0 Aba 7.0 Aa 0.5 Bb 

CV%  186.76   118.67  
 Dead seeds (%)  Accelerated Aging Test - AA (%) 

0 48.0 Aa   4.0 Bb 4.5 B  a  37.0 Ca 92.0 Aa 77.5 Ba 
15 40.0 Aa 14.5 Ba 6.5 C  a  36.5 Ba 81.5 Aab 91.0 Aa 
30   9.5 Ac   0.5 Bb 2.5 ABa  43.0 Ba 74.5 Ab 82.5 Aa 
45 31.0 Ab   5.0 Bb 7.0 B   a 

 
35.0 Ca 56.5 Bc 80.0 Aa 

CV%  30.17   12.76  
 Dormancy after AA (%)  Seedling emergence in the field (%) 

0   4.0 Ab   0.0 Ab   0.0 Ab  40.3 Bc 82.5 Aab 80.5 Aa 
15   0.0 Ab   4.5 Ab   0.0 Ab  43.5 Bbc 77.0 Aab 84.3 Aa 
30 42.0 Aa 17.5 Ba   0.0 Cb  58.3 Ba 83.0 Aa 83.3 Aa 
45   0.0 Bb   0.0 Bb 15.5 Aa 

 
50.3 Bab 73.0 Ab 80.8 Aa 

CV%  68.13   7.31  
 Initial seed water content (%)  Seed water content after AA (%) 

0 7.0 6.3  6.7  28.8 33.9 28.0 
15 7.1 6.6 6.4  32.7 37.5 29.0 
30 6.6 6.4 6.4  37.2 34.1 28.6 
45 7.0 6.1 6.7 

 
32.4 24.2 36.7 

CV%  0.93   5.59  
Means in the same column, followed by the same small letter, and in the same line, by the same capital letter, are not statistically 
different at the level of 5% of probability according to the Tukey test (P < 0.05). CV%: Coefficient of Variation. 

 
The lower weight of the seeds seems to have 

hampered the seeds physiological quality, since the 
Lisa Grande Portuguesa cultivar, as a general result, 
showed the highest proportions of dead seeds and 
also was the one displaying the lowest vigor, 
according to results of the first count of 
germination, accelerated aging, seedling emergence 
in the field, and germination tests (Table 2). 

In a similar way, it was found that carrot 
seeds of greater sizes exhibited the highest 
physiological potential since they had larger storage 
tissues, unlike smaller seeds, which tended to low 
germination results and low vigor seedlings 
(SANTOS et al., 2010; MARTINS et al., 2013). 

However, after 30 days of vernalization, 
seeds of Lisa Grande Portuguesa cultivar showed 



1775 
Floral induction, production…  MARTINS, C. C. et al. 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1771-1777, Nov./Dec. 2015 

highest germination percentage, similar to the other 
cultivars, and lower percentage of dead seeds (Table 
2). This phenomenon is caused by metabolic 
adaptations of biannual species of temperate climate 
for the survival and perpetuation of the species 
under ecological conditions of freezing winters and 
springs with mild temperatures, as simulated by 
vernalization (NASCIMENTO; GUEDES, 1988; 
MARTINS et al., 2013) 

Cultivars and vernalization periods did not 
affect the percentage of abnormal seedlings, which 
were relatively low (between 0.0 and 1.5%), 
indicating that the treatments had no influence on 
this characteristic. 

Vigor level of the parsley seeds of the Lisa 
Grande Portuguesa cultivar, as evaluated by the first 
count of germination and seedling emergence in the 
field tests, was favorably influenced by the 
vernalization treatment of the plants for 30 and 45 
days. Particularly the vernalization period of 30 
days also resulted in the production of seeds of the 
highest germination with the lowest percentage of 
dead seeds and these results were significantly 
better than the others.  

The accelerated aging test did not detect 
significant differences in the vigor of seeds of the 
Lisa Grande Portuguesa and Chacareira cultivars 
ascribable to vernalization. Though the seeds of the 
Caipira cultivars produced under conditions of 
vernalization for 30 and 45 days were of lower 
vigor, these results should be interpreted carefully 
since they were not confirmed by the other vigor 
tests. The results obtained for 30 days of 
vernalization could be ascribed to seed dormancy 
imposed to the seeds by the high temperature and 
relative humidity values characteristics of the 
accelerated aging procedure.   

In this research, when the accelerated aging 
test results were being evaluated, a high proportion 
of non-germinated seeds seemed not to have 
imbibed water. Thus a decision of keeping those 
seeds in the moist substratum for 28 days was made; 
that number of days would be the date of the final 
count in a standard germination test, followed by the 
procedure of submitting those firm, non-germinated, 
seeds to the tetrazolium test, to verify if their non 
germinability was due to their being dormant or 
dead.  

This procedure allowed to verify that the 
seeds of the Lisa Grande Portuguesa, Caipira and 
Chacareira cultivars resulting from the vernalization 
treatments of 30, 30, and 45 days, showed, after 
accelerated aging, dormancy proportions of 42, 18, 
and 16%, respectively. It also permitted to verify 
that the plants of some parsley cultivars, submitted 

to 5 °C for periods between 30 and 45 days, produce 
seeds that may show dormancy, if submitted to high 
temperature and relative humidity values (provided, 
in this research work, by the conditions of the 
accelerated aging test). 

As observed in this research, extreme 
conditions of temperature have been reported to be 
able to bring about dormancy in seeds as a defense 
mechanism to preserve seed viability under adverse 
conditions (MARCOS-FILHO, 2005; VIVIAN et 
al., 2008; OLIVEIRA et al., 2011; CARVALHO; 
NAKAGAWA, 2012).  

This is an important information for parsley 
seeds, since factors associated with the occurrence 
of dormancy in parsley seeds have not been clarified 
and the dormancy of those seeds is a common 
problem for the production of this species, causing 
tardiness and low uniformity in seedling emergence 
(TRINCA, 2007). 

Caipira cultivar seeds production was 
hampered by the vernalization treatment for 15 days 
since they presented lower germination and higher 
proportion of dead seeds, probably due to genetic 
factors for ecological adaptation (MARTINS et al., 
2013). On the other hand, this deleterious effect was 
not verified when seed vigor was determined by the 
first count of germination and seedling emergence 
in the field tests. 

For the Caipira cultivar the vernalization 
periods did not promote the production of seeds 
with germination speed (first count of germination 
test) and percentage of seedling emergence in the 
field different from the non-vernalized plants, thus 
indicating that the vernalization of the plants of that 
cultivar is not justifiable.  

There are studies on genetic breeding and 
vernalization of carrot seed that verified different 
responses among genotypes for temperatures and 
periods of vernalization on the viability, vigor and 
seed germination (NASCIMENTO; GUEDES, 
1988; MARTINS et al., 2013; MARTINS et al., 
2014). 

Among the evaluated cultivars, Chacareira 
was the least influenced by vernalization as to seeds 
physiological quality since, among the evaluated 
characteristics, only the rate of dormancy before and 
after the accelerated aging treatment were affected. 
Increasing periods of vernalization induced 
secondary dormancy in response to cold in Caipira 
cultivar seeds, with higher production of dormant 
seeds before the accelerated aging test. The opposite 
effect was observed for the Chacareira seeds while 
the Lisa Grande Portuguesa cultivar was not 
influenced by that factor. These differences between 
cultivars are related to genetic causes and variables 



1776 
Floral induction, production…  MARTINS, C. C. et al. 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1771-1777, Nov./Dec. 2015 

responses to environmental stimuli (CARVALHO; 
NAKAGAWA, 2012; MARTINS et al., 2014).  

The initial parsley seed water content was 
between 6.1 and 7.1%. This difference, from a 
biological point-of-view, is considered non-
significant, thus allowing to conclude that the tests 
results were not affected by differences in metabolic 
activity, the speed of moistening and seed 
deterioration due to the initial seed moisture. 
Recommendation is made that differences in seed 
moisture content before the aging of seed samples 
are not larger than 2 percentage points (MARCOS-
FILHO, 2005). 

For the comparison of one thousand seeds 
weight, seed water content should also be 
approximately the same for the different samples 

(BRASIL, 2009). These similar and relatively low 
moisture contents may be attributed to the low 
relative humidity of the air at the harvesting period 
and the period previous to the tests run to evaluate 
seed quality.  
 
CONCLUSIONS  

 
Parsley seed production and floral induction 

are not affected by vernalization process, however, 
it promotes changes on seed quality.  

Parsley seeds dormancy may be induced by 
the vernalization of the plants for periods of 30 to 45 
days, depending on cultivar, when followed by the 
submission of the seeds to adverse conditions (high 
temperature and relative humidity). 

 
 

RESUMO: Na produção de sementes de salsa (Petroselinum crispum) recomenda-se o cultivo em locais de 
baixas temperaturas para possibilitar a emissão do pendão floral. O objetivo do trabalho foi verificar o efeito da 
vernalização (0, 15, 30 e 45 dias) na indução floral, produção e qualidade de sementes de salsa. Dez plantas de três 
cultivares (Caipira, Chacareira e Lisa Grande Portuguesa (O. Enke)) cultivadas em vasos por seis meses, foram submetidas 
à vernalização a 5 °C por 0, 15, 30 e 45 dias. Após o tratamento, foram transferidas para casa-de-vegetação e avaliadas 
quanto à época e porcentagem de florescimento, produção de sementes por planta e qualidade das sementes. A qualidade 
foi avaliada por meio da determinação da massa de mil sementes, teste de germinação (porcentagens de plântulas normais, 
anormais, sementes dormentes e mortas), primeira contagem de germinação, teste do envelhecimento acelerado, 
dormência após o envelhecimento acelerado, emergência de plântulas em campo, teor de água das sementes antes e após o 
envelhecimento acelerado. Concluiu-se que a vernalização não promoveu a indução floral e a produção de sementes. Para 
a cultivar Lisa Grande Portuguesa (O. Enke), a vernalização da planta por 30 dias possibilitou a produção de sementes com 
maior germinação e vigor. A dormência das sementes pode ser causada pela vernalização das plantas por períodos entre 30 
e 45 dias, dependendo da cultivar, seguida de exposição das sementes produzidas a condições de altas temperaturas e 
umidade relativa (41 °C/100%UR/72h).  
 

PALAVRAS-CHAVE: Petroselinum crispum. Florescimento. Dormência. Vigor. Hortaliças. 
 

 
REFERENCES 
 
ALESSANDRO, M. S.; GALMARINI, C. R. Inheritance of vernalization requirement in carrot. Journal of the 
American Society for Horticultural Science, Alexandria, v. 132, p. 525–529, 2007.  
 
ANDRADE, R. N. B; SANTOS, D. S. B.; SANTOS-FILHO, B. G.; MELLO, V. D. C. Testes de germinação e 
de tetrazólio em sementes de cenoura armazenadas por diferentes períodos. Revista Brasileira de Sementes, 
Brasília, v. 18, n. 1, p. 108-116, 1996. http://dx.doi.org/10.17801/0101-3122/rbs.v18n1p108-116 
 
BRASIL. Portaria nº 457, 18 de dezembro de 1986. Diário Oficial da União, Poder Executivo, Brasília, 23 
dez., p. 19653. 1986. 
 
BRASIL. Ministério da Agricultura, Pecuária e Abastecimento. Regras para análise de sementes.  Secretaria 
de Defesa Agropecuária. Brasília: MAPA/ACS, 2009. 395p. 
 
CARVALHO, N. M.; NAKAGAWA, J. Sementes: ciência, tecnologia e produção. 5.ed. Jaboticabal: FUNEP. 
2012. 590p.  
 
CUNHA, A. R.; MARTINS, D. Classificação climática para os municípios de Botucatu e São Manuel, SP. 
Irriga, Botucatu, v. 14, n. 1, p. 1-11, 2009. 



1777 
Floral induction, production…  MARTINS, C. C. et al. 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1771-1777, Nov./Dec. 2015 

FILGUEIRA, F. A. R. Novo manual de olericultura: agrotecnologia moderna na produção e comercialização 
de hortaliças. 2ed. Viçosa: UFV. 2003. 412p. 
MARCOS-FILHO, J. Fisiologia de sementes de plantas cultivadas. Piracicaba: FEALQ. 2005. 495p. 
 
MARTINS, C. C., SILVA, N., MACHADO, C. G. Carrot seed size and progenies influence on seed 
physiological quality and plant productivity performance. International Journal of Food, Agriculture and 
Environment, Finland, v. 11, n. 3/4, p. 1143 - 1147, 2013 
 
MARTINS, C. C., SILVA, N., MACHADO, C. G. Testes para a seleção de populações de cenoura visando ao 
vigor e à longevidade das sementes. Ciência Rural, Santa Maria, v. 44, n. 5, p. 768-775, 2014. 
http://dx.doi.org/10.1590/S0103-84782014005000001 
 
NASCIMENTO, W. M. Produção de sementes de hortaliças para a agricultura familiar. Brasília, DF: 
Embrapa Hortaliças. 2005. 15p. (Embrapa Hortaliças. Circular Técnica, 35).  
 
NASCIMENTO, W. M.; GUEDES, A. C. Efeito do tempo de frigorificação das raízes na produção e qualidade 
de sementes de cenoura, cv. Brasília. Horticultura Brasileira, Brasília, v. 6, n. 2, p. 7-9, 1988. 
 
OLIVEIRA, J. A.; SILVA, T. T. A.; VON-PINHO, E. V. R.; ABREU, L. A. S. Secagem e armazenamento de 
sementes de sorgo com alto e baixo teor de tanino. Revista Brasileira de Sementes, Londrina, v. 33, n. 4, p. 
699-710, 2011. http://dx.doi.org/10.1590/S0101-31222011000400012 
 
RODO, A. B.; PANOBIANCO, M.; MARCOS-FILHO, J. Metodologia alternativa do teste de envelhecimento 
acelerado para sementes de cenoura. Scientia Agrícola, Piracicaba, v. 57, n. 2, p. 289-292, 2000. 
http://dx.doi.org/10.1590/s0103-90162000000200015 
 
SAMUOLIENĖ, G.; DUCHOVSKIS, P.;  URBONAVICIŪTĖ, A.;  SABAJEVIENĖ, G. Flowering initiation 
in plants of different Apiaceae species. Zemdirbyste-Agriculture, Lithuania, v. 96, n.3, p. 186-198, 2009. 
 
SANTOS, V. J.; GARCIA, D. C.; LOPES, S. J.; EICHELBERGER, L. Qualidade fisiológica de sementes de 
cenoura classificadas por tamanho. Ciência Rural, Santa Maria, v. 40, n. 9, p. 1903-1908, 2010. 
http://dx.doi.org/10.1590/S0103-84782010000900008 
 
TRINCA, J. R. Produção de sementes de salsa. In: CURSO SOBRE TECNOLOGIA DE PRODUÇÃO DE 
SEMENTES DE HORTALIÇAS, 7, 2007, Brasília, DF. Anais... Brasília: Embrapa Hortaliças. 2007. 1CD. 
 
VERDIAL, M. F.; TESSARIOLI-NETO, J.; MINAMI, K.; SCARPARE-FILHO, J. A.; CHRISTOFFOLETI, P. 
J.; SCARPARE, F. V.; BARELA, J. F.; DEL-AGUILA, J. S.; KLUGE, R. A. Vernalização em cinco cultivares 
de morangueiro. Ciência Rural, Santa Maria, v. 37, n. 4, p. 976-981, 2007. http://dx.doi.org/10.1590/S0103-
84782007000400009 
 
VIEIRA, R. D.; CARVALHO, N. M. Testes de vigor em sementes. Jaboticabal: FUNEP, 1994. 164p. 
 
VIVIAN, R.; SILVA, A. A.; GIMENES, JR., M.; FAGAN, E. B.; RUIZ, S. T.; LABONIA, V. Dormência em 
sementes de plantas daninhas como mecanismo de sobrevivência: breve revisão. Planta Daninha, Viçosa, v. 
26, n. 2, p. 695-706, 2008. http://dx.doi.org/10.1590/s0100-83582008000300026