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105 
Original Article 

Biosci. J., Uberlândia, v. 33, n. 1, p. 105-112, Jan./Feb. 2017 

VISUAL SYMPTOMS OF NUTRIENT DEFICIENCIES IN Physalis peruviana L.  
 

SINTOMAS VISUAIS DE DEFICIÊNCIAS NUTRICIONAIS EM FISALIS, Physalis 
peruviana L.  

 
Enilson de Barros SILVA1; Albertir Aparecido SANTOS1; Alex Macário de MATTOS1;  

Ari Medeiros BRAGA NETO1; Maria do Céu Monteiro da CRUZ1;  
Rodrigo Amato MOREIRA1; Valter Carvalho de ANDRADE JÚNIOR1;  

Emerson Dias GONÇALVES2; Luiz Fernando de OLIVEIRA2 
1. Departamento de Agronomia, Universidade Federal dos Vales do Jequitinhonha e Mucuri - UFVJM, Diamantina, MG, Brasil. 

ebsilva@ufvjm.edu.br. 2. Empresa de Pesquisa Agropecuária do Estado de Minas Gerais - Epamig, Maria da Fé, MG, Brasil. 
 

ABSTRACT: The physalis production has caused interest of producers, consumers and traders due to its easy 
growing, high nutritional value and economic value added. The objective of this study was to evaluate the growth and 
characterize the symptoms of macro and micronutrient deficiencies in physalis seedlings (Physalis peruviana L.). The 
seedlings were grown in complete nutrient solution and also in solutions with individual omissions of N, P, K, Ca, Mg, S, 
B, Cu, Fe, Mn and Zn, using the missing element technique. Visual symptoms of nutrient deficiency and the dry matter 
production of shoot and root, respectively taken at 68 and 150 days after treatment application were evaluated. Omissions 
of macro and micronutrients caused visual symptoms of nutrient deficiencies common to other species. Nutrient 
deficiencies limited the total dry matter production in the following order: N > S> P> K > Ca > Mg for macronutrients and 
Fe > B > Zn > Mn > Cu for micronutrients, respectively. 

 
KEYWORDS: Physalis peruviana L. Visual diagnosis. Missing element. Nutrient solution. 
 

INTRODUCTION 
 
Over these past few years, the production of 

small fruits in Brazil, which encompasses a number 
of species such as blackberry, raspberry, blueberry, 
strawberry and physalis has aroused, the attention of 
consumers, fruit processors, trading agents, small 
producers that compose family farming, as well as 
producers of medium and large size 
(FACHINELLO et al., 2011). 

The Physalis peruviana L. (physalis) is a 
herbaceous plant of perennial habit, that belongs to 
the Solanaceae family, which is characterized by 
producing fruits of beautiful visual appearance, 
sugary and with good content of vitamin A, C, iron 
and phosphorus, besides presenting numerous 
medicinal properties (FISCHER et al., 2014). 

Although it has perennial habit, physalis is 
grown as an annual crop when production is done in 
commercial scale. Physalis production has become 
an excellent alternative for small and medium 
Brazilian producer who has an interest in production 
and trade of fruits, due to this culture is a rustic 
plant, easy growing, and with great adaptability in 
different regions of the country. It is a species of 
great nutritional and economic value with a 
promising future, which is being developed in the 
small fruit plantations, and its fruit is enjoyed by 
high-income consumers (FISCHER et al., 2014). 
Origin center of physalis is not known, but most 

studies indicated the Andes region (GONZÁLEZ et 
al., 2008). 

Although it is a rustic plant, physalis is 
demanding in nutrients, and in Brazil, studies on its 
nutritional requirement are still incipient. There are 
a few parameters for fertilizer recommendation and 
nutritional requirement of this culture, and usually, 
these recommendations are made using as base 
search results from other regions, or using fertilizer 
recommendation for the tomato crop 
(IANCKIEVICZL et al., 2013). 

Then, the developing of programs for 
fertilizing agricultural crops has a huge importance, 
and they should be preceded by studies able to 
evaluate the consequences of mineral deficiencies 
on the growing and developing of plants. The 
knowledge of visual symptoms of nutrient 
deficiencies is also useful for decision making about 
the need to conduct fertilization (SILVA et al., 
2009). Thus, it is very important to know the 
nutritional aspects of this plant, as soil and climatic 
variations between different regions of Brazil, 
which can influence the fertilization and cultural 
practices to be adopted for each region. Since, the 
adoption of the same agricultural practice for 
different regions can reduce the culture developing, 
not expressing the full productive potential of 
culture. 

Received: 05/01/16 
Accepted: 05/12/16 



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Biosci. J., Uberlândia, v. 33, n. 1, p. 105-112, Jan./Feb. 2017 

The objective of this study was to evaluate 
the growing and to characterize the symptoms of 
nutrient deficiencies in physalis seedlings. 
 
MATERIAL AND METHODS 

 
The experiment was carried out in a 

greenhouse of the Agronomy Department at 
Universidade Federal dos Vales do Jequitinhonha e 
Mucuri (UFVJM), Diamantina, Minas Gerais State, 
Brazil (18° 12’ S, 43° 34' W, altitude of 1,350 m). 
The experimental was designed in randomized 
blocks with three replications and twelve treatments: 
complete solution and the individual omissions of 
N, P, K, Ca, Mg, S, B, Cu, Fe, Mn and Zn, totaling 
36 experimental plots with a plant in each pot. 

Physalis seeds were collected manually 
from plants grown in the horticulture sector of 
UFVJM, Diamantina, MG, Brazil. After a week, the 
seeds were sown in trays of 128 cells, using a 
commercial substrate, Bioplant®. The seedlings 
were grown in a greenhouse and irrigation was 
made by micro sprinklers twice a day. 

A month after seedling emergence, it was 
performed the roots wash to remove the substrate 
bonded, and it was made the transfer of seedlings 
for hydroponic pots of black color with 3.0 L 
capacity, with addition fo 2.5 L of nutrient solution 
prepared in accordance to Clark (1975). 

Solutions with ionic strengths of 25, 50, 75 
and 100 % were used. The seedlings were kept in 
each concentration for one week, using a continuous 
artificial aeration system. During this adaptation 
period, in the first and second week, it was supplied 
nutrient solution contained only macronutrients. 
And, in the third and fourth week, it was supplied 
nutrient solution with 50 and, 75% of 
macronutrients, respectively, and 10 % of the ionic 
strength of micronutrients. In the fifth week, 100 % 
of the ionic strength of all nutrients was supplied by 
the nutrient solution. The treatments with complete 
solution and with absence of nutrients studied were 
supplied in the sixth week. The solutions with 
different treatments were changed weekly, during 
the 150 days of the experiment conduction. 

The solutions were prepared with analytical 
reagents, and the complete nutrient solution was 
prepared in accordance to Clark (1975) as 
following: 114.2 mg N (N-NO3

- : N-NH4
+ ratio 8:1); 

2.2 mg P; 70.2 mg K; 104.4 mg Ca; 14.4 mg Mg; 16 
mg S; 209 µ g B; 32 µ g Cu; 2128 µ g Fe; 385 µ g and 
131 µ g Zn Mn per liter of solution. For the other 
treatments, the nutrients concentrations were 
identical to those of the complete solution, except 
for the omitted nutrient. 

Symptoms of nutrient omission were 
described and photographed 68 days after the 
treatments application. After 150 days, the plants 
were harvested, being made the shoot and roots 
separation. The collected material was washed in 
distilled water, packed in drilled paper bags and 
placed for drying in an oven with forced air 
circulation at a temperature of 65 °C until constant 
weight. After drying, the harvested plant material 
was weighed. 

Data from dry mass of shoots and roots 
were subjected to analysis of variance, and the 
averages of the treatments were compared by the 
Scott & Knott test at 5 % of probability. 

 
RESULTS AND DISCUSSION 

 
All treatments with disabilities had dry 

matter production of shoots, roots and total below 
the complete treatment (Table 1). Macronutrients 
that most affected the production of total dry matter 
were N, S, P, K, Ca and Mg, down 67, 63, 54, 45, 
43 and 33 % respectively in relation to the complete 
treatment. The order of limitation was N > S > P > 
K > Ca > Mg for macronutrients. 

Macronutrients, N, S, P, K and Ca did not 
statistically differ among themselves for the shoot 
and total dry matter production, both with 
production below complete treatment, that the N and 
P omission were the least limited the root dry matter 
production of physalis plants (Table 1). Batista et al. 
(2003) found lower shoot and total dry matter 
production in soursop in the omission of N, the first 
limiting nutrient, followed by Ca and P. In the 
present study, among the macronutrients, the N was 
also the most limiting element with the N, P and Ca 
being the first, third and fifth macronutrient, 
respectively, most limiting for total dry matter 
production. Alves et al. (2008) in sugar beet plants 
and, Lavres Junior et al. (2009) in castor bean plants 
also observed reduction in root, shoot and total dry 
matter production when in the N absence. 

The S was the second macronutrient most 
limiting dry matter production, mainly the roots of 
physalis (Table 1). This fact showed that it is 
importance of considering the supply of this 
macronutrient, and that the use of fertilizers such as 
superphosphate simple and potassium sulphate at 
planting would be feasible to contain this nutrient. 
Conversely, Barroso et al. (2005) with work done 
with teak (Tectona grandis), Alves et al. (2008) with 
sugar beet plants, Silva et al. (2009) with physic nut, 
they found their works that S had the lowest 
reductions in total dry matter production. However, 
for N, K, P and Ca it was found higher decrease in 



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total dry matter production of sugar beet plants 
(ALVES et al., 2008). 

 

 
Table 1. Shoot dry matter, roots dry matter, and total dry matter production of physalis seedlings grown in 

complete nutrient solution and omissions of nutrients, at 150 days after treatment application 
Treatment(1) Dry matter production 
 Shoot 

(g) 
Root 
(g) 

Total 
(g) 

Complete 20,18 a 4,64 a 24,82 a 
Omission N 5,06 c 3,16 b 8,21 c 
Omission P 6,91 c 4,57 a 11,48 c 
Omission K 11,24 c 2,42 c 13,66 c 
Omission Ca 11,23 c 2,84 c 14,07 c 
Omission Mg 13,95 b 2,71 c 16,66 b 
Omission S 7,44 d 1,83 d 9,26 c 
Omission B 12,25 b 2,71 c 14,96 c 
Omission Cu 17,17 a 2,37 c 19,54 b 
Omission Fe 9,59 c 2,21 c 11,80 c 
Omission Mn 14,37 b 2,33 c 16,69 b 
Omission Zn 12,94 b 3,25 b 16,19 b 
CV (%) 15,23 17,11 14,73 
(1)Averages followed by the same letter in the columns do not differ by the Scott & Knott test at 5% probability. 

 
The P and K were the third and fourth 

macronutrients, respectively, that caused major 
reductions in dry matter production when in 
deficiency, except for the P omission in roots dry 
matter production of physalis (Table 1). Alves et al. 
(2008) in sugar beet also observed drastic reductions 
in the roots, shoot and total dry matter production 
when K was absent. Silva et al. (2009) observed 
smaller reductions (32 %) in the absence of P in 
total dry matter of physic nut seedlings. 

The Ca was the fifth macronutrient most 
limiting of total dry matter production in physalis, 
and significant difference was found between this 
element and Mg (Table 1), which in turn was less 
limiting to the production of total dry matter, 
statistically differentiating itself from the other 
macronutrients (N, S, P, K and complete). These 
reductions in total dry matter production caused by 
the omission of Ca and Mg, indicated the need for 
liming with calcitic limestone, and generally, 
dolomitic and magnesium limestone are more 
recommended than the calcite. Silva et al. (2009) 
found in a study of physic nut that Ca, Mg and K are 
the macronutrients most limiting for total dry matter 
production. 

Comparing the full treatment with the 
treatments without some of micronutrients studied 
(Table 1), it was observed that there were major 
limitations when Fe and B were absent, being the 
limit order was Fe > B > Zn > Mn > Cu, with 
decrease of 52, 40, 35, 33 and 21 % respectively. 
Lange et al. (2005) also found severe reductions in 

total dry matter production in castor bean caused by 
the omission of Fe and B. In physic nut, Silva et al. 
(2009) also observed a drastic reduction in the total 
dry matter production in the absence of Fe, and 
unlike the present study, the absence of B showed 
higher total dry matter production, which was 
justified by the overgrowth caused by the absence of 
this micronutrient. 

In relation to complete treatment, the Zn, 
Mn and Cu caused a reduction in total dry matter 
production significantly lower, than the reductions 
observed for Fe and B absences (Table 1). Contrary 
results in relation to Mn were found by Lange et al. 
(2005) in castor bean, in this study, the Mn 
deficiency caused the higher reductions in total dry 
matter production. Silva et al. (2009) found a drastic 
reduction in shoots, roots and total dry matter 
production physic nut in Cu omission. 

Deficiency symptoms of all nutrients were 
completely visible to 68 days after the treatment 
application (Figure 1). The complete treatment did 
not show any foliar symptoms during the 
experiment conduction. The plant physalis with 
complete fertilization showed vigorous with showy 
green leaves and flowering at 84 days after 
treatment application.  

Only at the experiment end, 150 days after 
treatment application, a reduced internerval 
chlorosis was observed on the leaves (Figure 1), 
possibly, this was due to the grown plant demanding 
a higher concentration of nutrients for this stage 
development of plant physalis. 



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Complete 

 

Omission N 

 

Omission P 

 

Omission K 

 

Omission Ca 

 

Omission Mg 

 

Omission S 

 

Omission B 

 

Omission Cu 

 

Omission Fe 

 

Omission Mn 

 

Omission Zn  

 
Figure 1. Nutritional deficiency symptoms on physalis plant leaves subjected to treatments on complete 

nutrient solution and with the nutrients omission, 68 days after treatment application. 
 
The N omission caused a drastic reduction 

in the plants growth when compared to plants 
cultivated in complete nutrient solution (Table 1). 
At 68 days, after treatment application, a light green 
color was observed on all leaves of plants cultivated 
without N supply (Figure 1), and flower buds 
emission occurred at 70 days. After 84 days, the 
oldest leaves presented a yellowish color evenly, 

and the new leaves remained with a light green 
color. With the advance of symptoms, to 103 days 
all leaves were yellow, being that the oldest leaves 
presented this symptom with higher intensity, 
causing necrosis and leaf senescence. The 
symptoms due to N omission were also observed by 
Martínez et al. (2009) in physalis plants in an 
experiment conducted in Colombia, wherein the 



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plants with deficiency of N and K, presented 
symptoms more severe in relation to plants 
submitted to other macronutrients deficiencies. In 
study with passion fruit, Freitas et al. (2011) also 
found N deficiency symptoms using the missing 
element technique, and the N deficiency symptoms 
were the first to manifest in the leaves. Other 
authors had also described similar symptoms in teak 
plants (BARROSO et al., 2005) and sugar beet 
(ALVES et al., 2008), respectively. 

At 68 days, in treatments with the P 
omission was observed an intense green color on all 
leaves with ripples being formed on the younger 
leaves edges (Figure 1). The flower buds emission 
occurred at 84 days after treatment application. 
After 103 days, the plants presented their new 
leaves wrinkled up and, with ripples on the edge, 
already the oldest leaves presented a dull green 
color, with bright strong green spots and with waxy 
appearance. The oldest leaves presented thick and 
brittle texture. The P deficiency dramatically 
affected the plants growth when compared to the 
complete treatment (Table 1). Martínez et al. (2009) 
observed similar features in the culture of physalis. 
Other authors also observed similar characteristics 
in soursop (BATISTA et al., 2003) and sugar beet 
(ALVES et al., 2008) by the missing element 
technique in nutrient solution. 

Due to K omission a chlorosis was observed 
in the center of oldest leaves, at 68 days after 
treatment application (Figure 1). Unlike the 
symptoms observed in leaves of other crops with 
deficiency of this nutrient, wherein the chlorotic 
effect commonly appear in the oldest leaves apex 
until to the limbus base (SILVA et al., 2009). The 
flower buds emission occurred at 84 days after 
treatment application. In oldest leaves, it was 
observed intense and bright green spots with waxy 
aspect and irregular small marks light-colored with 
wet aspect, which may be related to the collapse of 
chloroplasts (MARTÍNEZ et al., 2009). At 103 
days, these symptoms advanced and the marks were 
united to other chlorotic spots, acquiring an orange 
tonality, after this, there was necrosis and leaf 
senescence. Martínez et al. (2009) also observed 
similar symptoms of K deficiency in physalis plants 
when grown in nutrient solution. 

Plants deficient in Ca showed symptoms at 
57 days after treatment application, and these were 
clearly visible after 68 days, when new leaves 
crinkled and shriveled, and over time the oldest 
leaves also presented these symptoms. After 103 
days, we could observe the developing yellowish 
color and necrosis of young leaves edges, after this 
there was necrosis of the plant apex. Similar 

symptoms were observed in studies performed with 
sugar beet plants (ALVES et al., 2008) and passion 
fruit (FREITAS et al., 2011) in absence of Ca. 

Although, the omission of all 
macronutrients had caused significant decreases in 
the growth of physalis in relation to the complete 
treatment (Table 1). The Mg was macronutrients 
that less affected the plant growth. In Mg absence, it 
was observed flower buds emission at 84 days. At 
68 days, on oldest leaves, the symptoms started with 
a slight yellowing, advancing for a more intense 
internerval chlorosis with a thick reticulated aspect 
(Figure 1). With passing of the days, the symptoms 
progressed more rapidly, causing necrosis of these 
leaves. After this, the younger leaves also presented 
internerval chlorosis. Freitas et al. (2011) observed 
similar symptoms in sweet passion fruit and Barroso 
et al. (2005) on teak plants with symptoms of 
chlorosis internerval in old leaves with a narrow 
strip of green tissue along the veins, and the 
progression deficiency leaves became yellow, with 
margins of the necrotic and intense falling leaves. 

In turn, the S omission caused severe 
symptoms in the plysalis plant, as large reduction in 
growth (Table 1). At 68 days after treatment 
application, it was observed a light green color 
throughout the plant. With the symptoms advance 
there was a general chlorosis in new leaves, and 
then, the chlorosis had become widespread 
throughout the plant. These symptoms were more 
intense on younger leaves, which acquired a yellow 
color, with green veins and white contours (Figure 
1). At 109 days it could be perceived the all the 
leaves whitening, and, on youngest leaves were 
observed the necrosis of apex and of the edges. 
Silva et al. (2009) observed similar symptoms in 
leaves of physic nut plants cultivated in S omission; 
however, these authors obtained the highest total dry 
matter between the macronutrients omissions in 
relation to complete treatment contrary to this work. 

The omission of all micronutrients caused 
reductions in physalis plant growth (Table 1), except 
for Cu. In the treatment with the B omission, the 
symptoms were observed at 68 days after treatment 
application (Figure 1), with overbudding at the plant 
top and small chlorotic spots on young leaves. The 
plants bloomed at 70 days after treatment 
application. At 84 days, anomalies were observed in 
the developing leaves, which were issued with 
various distortions, and also, it was observed the 
crinkling of new leaves which presented bright and 
intense green color with waxy appearance. From 
103 to 109 days after treatment application, the 
overbudding at the plant top was more intense, 
changing its architecture. Martínez et al. (2009) 



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observed similar symptom related to the plant 
architecture in physalis plants with cultivation in 
nutrient solution, due to malformation of all its 
structures and disorganization of meristems, 
providing the death of the apical meristem and 
lateral shoots. Lange et al. (2005) reported other 
features of symptoms in young leaves of castor bean 
with wrinkled and thick with winding down with 
deformation in the tissue at the junction region of 
the leaf blade lobes that migrated towards the 
central rib, giving the blade one rounded shape. At 
the end of development, B deficiency in castor bean 
caused loss of dominance due to the death of the 
apical bud, similar to this work. For Oliveira et al. 
(2009), in study performed with tomato cultivation, 
the B was bit limiting in the initial phase of 
development, possibly by the low need of the 
nutrient that stage where the amount provided in the 
adaptation phase supplied the need for culture in this 
period, unlike the present study there was low B 
supply in the adaptation phase of physalis seedlings. 

The total dry matter production under the 
Cu omission was statistically identical to the 
complete treatment (Table 1). The flowering 
occurred at 84 days after treatment application, as it 
occurred for complete treatment. Due to the small 
amount of Cu demanded by the plant, possibly the 
amount provided in the adaptation phase had been 
enough so that plant had a good development and 
vigor during the initial stage (Figure 1). Oliveira et 
al. (2009) in a group of tomato salad observed no 
symptoms caused by Cu deficiency due to low 
demand for variety and possible that the quantity of 
nutrients provided in the adaptation phase has been 
enough to supply the need of culture. 

The Fe omission caused the most dramatic 
reduction in physalis plant growth when compared 
to effect due to omission of the other micronutrients 
studied (Table 1). The symptoms due to Fe omission 
manifested during the stage of seedlings adaptation 
in the nutrient solution, on the first and second 
week, due to nutrient solution had supplied only 
macronutrients, with ionic strengths of 25 %. 
However, there was a plant recovery when this 
element on the 3rd, 4th and 5th week, with ionic 
strengths of 10, 10 and 100 %, respectively. At 63 
days after starting the treatments, Fe deficiency 
symptoms were the first to appear, and initially, 
chlorosis resembling a mosaic was observed on the 
leaves developing present in the plant apex, and it 
was observed a chlorosis that started in the limbo 
base of expanded new leaves, which evolved 
towards the leaf center. After 68 days, the chlorosis 
manifested itself throughout the limbo of new 
leaves, and only a leaf part presented a little green 

color (Figure 1). With the advancement of these 
symptoms, newly expanded leaves became totally 
chlorotic, and later there was a whitening of these 
leaves. At 103 days after treatment application, it 
was observed necrosis that evolved from inside to 
outside of the leaves. The Fe omission led to a 
chlorosis generalized leaf entire, evolving for the 
whitening of leaves, and culminating in death of the 
plant apex. Oliveira et al. (2009) observed identical 
symptoms on tomato crops of the salad group with 
the first expression of Fe deficiency symptoms, 
about 3 to 4 days after Fe omission in the nutrient 
solution with new leaves presenting chlorosis which 
started at the base of the petiole and walking toward 
the tip of the leaves with increasing time deficiency; 
chlorosis achieved old leaves, so that whole plants 
became chlorotic and end of the cycle, the leaves 
had is totally whitened. 

With the omission of Mn, at 68 days after 
application of treatments, it was observed an 
internerval chlorosis with thick crosslinked aspects 
on young leaves (Figure 1). And, with the evolving 
of symptoms, the old leaves had presented the 
characteristics. The flower buds emission occurred 
at 84 days. These symptoms were similar to those 
described in castor bean by Lange et al. (2005) in 
which younger leaves Mn omission presented 
chlorosis internerval that looks thick crosslinked, 
i.e. the ribs and adjacent areas became dark green, 
while the rest of the leaf surface had become 
yellowish. 

In plants deficient in Zn, stretch marks 
perpendiculars to veins of the new leaves were 
observed at 68 days after starting treatments (Figure 
1). Flowering occurred at 70 days after treatment 
application. At 95 days, it was observed a large 
number of smaller sized leaves, thinner stem, a 
greater number of branches in relation to the 
complete treatment, and subsequently, there was 
chlorosis on old leaves. In castor bean, Zn omission 
caused no symptoms, this fact was due to the plant 
had been cultivated on complete solution during the 
adaptation phase (LANGE et al., 2005). In tomato, 
Zn omission caused symptoms that initially 
manifested in the young leaves, which showed slight 
chlorosis, with the intensification deficiency, the 
entire plant was struck, showing chlorotic leaves, 
coerces and wrinkled, shortening the ribs and 
thickening of the petiole (OLIVEIRA et al., 2009). 

 
CONCLUSIONS 

 
The limiting order for total dry matter 

production of physalis plant was N > S > P > K > 



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Biosci. J., Uberlândia, v. 33, n. 1, p. 105-112, Jan./Feb. 2017 

Ca > Mg for macronutrients, and Fe > B > Zn > Mn 
> Cu for micronutrients.  

The nutrients omissions to the physalis 
plants caused visual symptoms of nutrient 
deficiency, common to other species. 
 

ACKNOWLEDGEMENTS 
 
The Fapemig for financial support, the 

CNPq, the scholarship masters the first author, and 
the UFVJM, the infrastructure necessary for the 
experiment.

 
 
RESUMO: A produção de fisalis tem despertado interesse de produtores, consumidores e comercializadores 

devido seu fácil cultivo, grande valor nutricional e econômico agregado. O objetivo deste trabalho foi avaliar o 
crescimento e caracterizar os sintomas de deficiências de macro e micronutrientes em mudas de fisalis (Physalis peruviana 
L.). As mudas foram cultivadas em solução nutritiva completa e, também em soluções com omissões individuais de N, P, 
K, Ca, Mg, S, B, Cu, Fe, Mn e Zn, pelo uso da técnica do elemento faltante. Foram avaliados os sintomas visuais de 
deficiência de nutrientes, e a produção de matéria seca da parte aérea e das raízes aos 68 e 150 dias após a aplicação dos 
tratamentos, respectivamente. As omissões de macro e micronutrientes provocaram sintomas visuais de deficiências 
nutricionais comuns a outras espécies. As deficiências limitaram a produção de matéria seca total na seguinte ordem: N > 
S > P > K > Ca > Mg para macronutrientes e Fe > B > Zn > Mn > Cu, para micronutrientes, respectivamente. 

 
PALAVRA-CHAVE: Physalis peruviana L. Diagnose visual elemento faltante. Solução nutritiva. 

 
 
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