Influence of osmotic pressure on the growth of three species  
of genus Zoophthora

JERZY PIĄTKOWSKI and EWA KLICZKOWSKA

Institute of Genetics and Microbiology, University of Wrocław 
Przybyszewskiego 63/77, PL-51-148 Wrocław, jurekp@microb.uni.wroc.pl

Piątkowski J., Kliczkowska E.: Influence of osmotic pressure on the growth of three species of the 
genus Zoophthora. Acta Mycol. 43 (1): 49–55, 2008.

Strains accomodated in the genus Zoophthora are very sensitive to osmotic value of their 
habitat. Hipertonical molarity of buffers and NaCl decreases the growth, but this effect 
strongly depends on the species tested and on the kind of buffer. In 0.66% phtalan buffer 
the growth of Z. lanceolata is completely stopped whereas Z. psyllae and Z. aphrophora is 
inhibited only in 50% comparing to the control.

Key words: Zoophthora, osmotic pressure, influence of buffers on growth

INTRODUCTION

It is a well-established fact that many species of insects are infected and finally 
killed by fungi belonging to a variety of genera (Batko 1964a, b; 1974). One of them 
is the genus Zoophthora.

Investigations have been carried out into the use of entomopathogenic fungi as 
an alternative to chemical insecticides. However, entomopathogenic fungi are dif-
ficult to cultivate under laboratory conditions, so the researches have directed their 
attention to the factors that may influence the growth and germination of these spe-
cies (Freimoser et al. 1999) and thus facilitate their cultivation.

The available information about the physical factors affecting the physiology of 
the entomopathogenic fungi is rather poor. Research on a variety of physical factors 
has revealed that each species react differently to such factors. It has been noticed 
that the activity of entomopathogenic fungi against insects may depend on a season 
(Bajan, Kmitowa 1997; Krejzowa 1988). Although the seasons of the year them-
selves cannot be regarded as physical factors, we assume that the main factors that 
affect the physiological activity of the fungi in particular season are light, tempera-
ture and air humidity.  

Many investigations into the influence of temperature have been reported so far 
(Yendol 1968; Hall, Bell 1961). Temperature is of importance to the growth of the 

 ACTA MYCOLOGICA
 Vol. 43 (1): 49–55
 2008



50 J. Piątkowski and E. Kliczkowska 

entomopathogenic fungi and to their ability of infecting insects (Miętkiewski et al. 
1994). In some instances the influence of temperature is positive (it stimulates), in 
others a negative one. At temperatures lower than 8°C and higher than 36°C, the 
spores of Entomophthora virulenta are completely deactivated (Yendol 1968). Other 
investigations have revealed that the optimal temperature for the viability of the 
mycelium of particular fungal strain is also optimal for the viability of their spores 
(Brobyn et al. 1985). The photoperiodic effect (Feng, Xu 1998) or the effect of ultra-
violet light on some fungi has also been reported (Braga et al. 1999). 

A significant factor which influences the fungal metabolism is moisture. As for 
the entomopathogenic fungi, this is also a very important factor of their habitat, 
responsible for viability, rate of growth and intensity of sporulation. For Entomoph-
thora thaxteriana, and E. aphidis the optimal moisture of spore release ranges from 
70 to 90% at 20°C. As for the viability of the species, they may survive under these 
conditions for several days but in drier and colder air even for several weeks or 
months (Wilding 1973). 

Another important physical factor that affects the growth and sporulation of 
those fungi is light. Exposure to electromagnetic waves in the visible range accounts 
for the effect of periodity of sporulation. The sporulation of most entomopathogenic 
fungi is light-dependend, but there are species that sporulate at a faster rate in dark-
ness (Latge et al. 1978).

In our study reported on in this paper we cultivated three relative species of the 
genus Zoophthora on the solid full medium supplemented with saline, phosphate 
buffer or phtalane buffer at different concentrations. The available literature con-
tains no references to the importance of the osmotic value of the habitat to the 
physiological activity of fungi, involving the entomopathogenic strains.  

MATERIALS AND METHODS

The strains used in these tests: Zoophthora aphrophorae (Rostrup) Bałazy, Z. 
lanceolata Keller and Z. psyllae Bałazy, were received from Prof. Stanisław Bałazy, 
Research Centre for Agricultural and Forest Environment, Polish Academy of Sci-
ences. Z. aphrophora was isolated from Aphrophora sp. The species was previously 
described by Rostrup as Enthomophthora aphrophorae and a second time by Bałazy 
as Zoophthora miridis (Bałazy 1993). The name Z. aphrophora has been proposed re-
cently by prof. Bałazy (Bałazy 2003). Z. lanceolata was isolated from Empididae and 
Z. psyllae from Trioza urticae. All the strains were isolated in Bavaria, Germany.

The strains were stored on the solid medium supplemented with a hen egg-yolk at 
4°C. Before testing, small samples of mycelium were translocated onto the solid full 
medium – YPG, and cultivated at 210C in the dark for 5 days. Subsequently, small 
(7 mm diameter) discs of mycelium from the outer side of the cultivated fungus 
were cut out and translocated onto plates with solid full media (YPG) supplemented 
with buffers and/or NaCl at concentrations of 0.0066M, 0.066M and 0.66M. Use 
was made of phosphate and phtalan buffer according to the procedure described 
by Mejbaum-Katzenellenbogen and Mochnacka (1968). We also used media with 
0,0066M phosphate buffer supplemented with such an amount of NaCl that the final 
NaCl + buffer concentration amounted to 0.066M and 0.66M.  Each variant of the 
“strain+medium” was prepared in four repetitions, and statistical evaluation of the 



 Influence of osmotic pressure 51

diameter length was performed. Air humidity at the time of culturing approached 
55%.

The media were prepared according to the following scheme:
______________________________________________________
Components   ____________Medium  number
of medium I II III IV  V  VI  VII VIII IX X XI XII

Yeast extract
       [g]           10 10 10 10 10 10 10 10 10 10 10 10
Peptone [g]  10 10 10 10 10 10 10 10 10 10 10 10
Glucose [g]  20 20 20 20 20 20 20 20 20 20 20 20
Agar-agar [g]  20 20 20 20 20 20 20 20 20 20 20 20
NaCl [g] 0.38  3.85 38.6 -  - - -  -   - 3.47 34.7 -
Phosphate 
Buffer 0.66M
pH=6.2 [ml] - - - -  - - -  - 1000 -  - -
Phosphate 
Buffer 0.066M
pH=6.2 [ml] - - - -  - - -  1000 - -  - -
Phosphate 
Buffer 0.0066M
pH=6.2 [ml] - - - -  - -  1000    - - 1000 1000  -
Acidic phthalate
Buffer 0.66M
PH=6.2 [ml] - - - - - 1000   -   -  - -  -  -
Acidic phthalate
Buffer 0.066M
PH=6.2 [ml] - - - -  1000 -   -  - -  -  - -
Acidic phthalate
Buffer 0.0066M
pH=6.2 [ml] - - - 1000  -   -  - -  -    -  -  -  
H2O [ml]  1000 1000 1000 -  - -  - - - -  - 1000

RESULTS AND DISCUSSION

Figure 1 depicts the effect of osmothic prasure on the growth of the tree strains 
being tested (including statistically evaluated data).

As we can see, at salt concentrations providing an isoosmotic environment of the 
medium-variant I (0.0066M), Zoophthora psyllae grow at the fastest rate; the growth 
rate for Z. aphrophora being slower and that of Z. lanceolata the slowest one. In all the 
testing variants of the medium, the rate of mycelium growth of particular strain is simi-
lar in YPG (control, variant XII) and YPG suplemented with 0.066M buffer (IV, VII), 
or 0.0066M NaCl (I). This implies that low concentrations of Na2HPO4, KH2PO4, NaCl, 
and phthalate do not affect the rate of growth of the three fungal strains examined.

If the concentration of the phthalate buffer or NaCl amounts to 0.066M (II,V), 
Z. psyllae grows at the same rate as in the control, the diameter of the mycelium being 
45.6 mm, 51.7 mm and 46.6 mm, respectively. In the X variant, when the phosphate 





 Influence of osmotic pressure 53

Pseudocystidia are thought to be cells which perfore the cuticule of a host, enabling 
arising of conidiophores on outside of the host body (Brobyn, Wilding 1977).  

The morphologies of all these structures are of great importance to the differen-
tiation of the genus Zoophthora into particular species. But if we analyse the poly-
morphism and the extent to which the structures differ from one another, the differ-
ence will appear to be very smal in some instances. For example, on comparing the 
capillisporal structures as diagnostic features, one may conclude that the differences 
between the capillispore shapes are very subtile (Keller 1980; Ben-Ze’ev, Kenneth 
1981b).

When analysing the importance of morphological features to the diagnostics 
of fungal species, the question arises whether morphological differences are suf-
ficient to distinguish particular species. In our opinion the analysis of morphological 
characteristics should be supported by the analysis of physiological properties to a 
greater extent than it is now. 

The aim of our study was not to revise the systematic classification of the spe-
cies Z. aphrophora, Z. lanceolata or Z. psyllae. More species representing each of 
the genera should be tested so that conclusions can be drawn about the taxonomic 
value of osmotic pressure. Correct comparisons of the species require analysis at 
the molecular level – on the nucleotyde sequence in DNA. But, in our opinion, such 
properties of the strains as sensitivity to osmotic preassure or to other physiological 
factors, may be also useful in differentiating those species into particular systemati-
cal units.

The osmotic value of the fungal hyphe environment seems to be important, prob-
ably because of the exceptional sensitivity of the fungi to the decrease in water con-
centration inside the cells. The concentration of osmotically active substances in the 
fungal hyphe habitat, higher than the physiological ones accounts for the efflux of 
water from the inside of the cells. We woud like to emphasize that because of the 
high sensitivity of the fungi to osmotic value of the media used for their culturing 
is of great importance to the growth process, as well as to a variety of physiological 
processes, such as sporulation and release of secondary metabolites. But, as we can 
infer from the bars in  figure 1, the responses to the varying buffer concentrations 
differ remarkably from one strain to another.

The difference in sensitivity to the osmotic value of the environment between the 
fungal strains is also high, when compared the strains from not relative taxonomic 
units. For the yeast strains we used a storage medium, where one of the components, 
glycerol, accounted for 50% of the total content. In such medium the yeast cells can 
survive at temp. 710C for years, except the Zoophthora species, which survived only 
one day, when kept in this environment (results not published).

It is not clear why some fungal taxa are so sensitive to water amount. Particular 
physiological processes involved in this “water-dependence” have not been well rec-
ognized so far. Probably, some enzymes in “low water-sensitive” strains change their 
conformation, especially at an active centre, when water concentration changes. The 
level of this sensitivity varies from organisms to organisms. Water can be removed 
completely from yeast and bacteria, but they recover life activity in the water habitat. 
These differences in viability under low moisture conditions may be of great ecologi-
cal importance. 



54 J. Piątkowski and E. Kliczkowska 

The use of a media differing in osmotic values may be beneficial when detecting 
and investigating biochemical changes in fungal cell metabolism with the decrease 
in the water level. 

It is worth noticing that the buffers and NaCl not only decrease the growth of 
the strains but also the morphology (colour) of particular fungal colony is different, 
depending to the medium variant, as illustrated in the figure 2A, B.

The medium variants were prepared according to the procedure shown in the 
schema in materials and methods.

To sum up, the results suggest that osmotic pressure is one of the significant fac-
tors that affect growth and presumably other physiological processes of entomopath-
ogenic fungi belonging to the genus Zoophthora. It is obvious that other comparative 
investigation must be performed, using other species of this kind of fungi. 

REFERENCES

Bałazy S. 1993. Flora Polska. Grzyby (Mycota) 24:Owadomorkowe (Entomophthorales). W. Szafer Insti-
tute of Botany, Polish Academy of Sciences, Kraków.

Bałazy S. 2003. On some little known epizootics in noxious and beneficial arthropod populations caused 
by entomophthoralean fungi. Insect Pathogens and Insect Parasitic Nematodes IOBC Bulletin 26: 
63–68.

Batko A 1964a. Remarks on the genus Entomophthora. Bull. Acad. Pol. Ser. Sci. Biol. 12: 319–321.
Batko A. 1964b. On the new genera Zoophthora. Bull. Acad. Pol. Ser. Sci. Biol. 12: 323–326.
Batko A. 1974. Filogeneza a struktury taksonomiczne Entomophthoraceae  (Phylogenesis and taxonomic 

structure of Entomophthoraceae). (In:) C. Nowiński (ed.). Ewolucja biologiczna, szkice teoretyczne 
i metodologiczne. Polska Akad. Nauk, Ossolineum, Wrocław: 109–303.

Ben-Ze’ev I., Kenneth R. G. 1981. Zoophthora radicans and Zoophthora petchii sp. nov. (Zygomycetes: 
Entomophthorales) two species of the “sphaerosperma – group” attacking leafhoppersand froghop-
pers (Hom.). Entomophaga 26: 131–142.

Braga G., Messias C. L., Miller C. D., Flint S. D., Daldwell M., Anderson A. J., Roberts D. W. 1999. 
Effect of near ultraviolet light (UVA and UVB) on hydrated and germinating conidia of the genus 
Metarhizium.  XXXIII Annual Meeting of the SIP, Irvaine. SIP Program and Abstracts: 28.

Bajan C., Kmitowa K. 1997. Interactions between entomopathogenic and saprophytic fungi. Zar JA. Bio-Interactions between entomopathogenic and saprophytic fungi. Zar JA. Bio-
statical Analysis. 32: 47–63.

Brobyn P. J., Wilding N. 1977. Invasive and developmental processes of Entomophthora species infecting 
aphids. Trans. Brit. Mycol. Soc. 69: 349–366.

Brobyn P. J., Wilding N., Clark S. J. The persistence of infectivity of conigia of the aphid pathogen, Erynia 
neoaphidis on leaves in the field. Ann. Appl. Biol. 107: 365–376.

Feng M. G., Xu J. H. 1998. Photoperiods affect the growth and sporulation pattern of the liquid and plate 
cultures of the entomophthoralean fungus Pandora delphacis (Hori) Humber. (In:) VIIth Interna-
tional Colloquium on Invertebrate Pathology, Sapporo. Meetings Program and Abstracts: 55.

Freimoser M., Grundschoher F. Aebi M., Tuor U. 1999. Morphology and growth requirements of the 
thrips pathogenic fungus Enthomophthora thripidum in in vitro cultures. (In:) XXXIII Annual Meet-
ing of the SIP, Irvaine. SIP Program and Abstracts: 36.

Hall I. M., Bell J. V. 1961. Further studies on the effect of temperature on the growth of some  Entomoph-
thoraceus fungi. Journal of Insect Pathology 3: 289–296.

Keller S. 1980. Two new species of the genus Zoophthora Batko (Zygomycetes, Entomophthorales): Z. 
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Mejbaum-Katzenellenbogen W., Mochnacka I. 1968. Kurs praktyczny z biochemii. PWN Warszawa.
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116–121.



 Influence of osmotic pressure 55

Wpływ ciśnienia osmotycznego na wzrost trzech gatunków z rodzaju Zoophthora

S t r e s z c z e n i e

Informacje o wpływie czynników fizycznych na grzyby owadobójcze są w literaturze na-
ukowej raczej skąpe. Donosi się o znaczeniu temperatury, wilgotności powietrza, oraz długo-
ści działania światła na wzrost i sporulację wybranych gatunków. W niniejszej pracy przedsta-
wiono wyniki badań nad wpływem różnych stężeń buforu fosforanowego, ftalanowego oraz 
chlorku sodowego na wzrost szczepów trzech gatunków: Zoophthora lanceolata, Z. psyllae 
i Z. aphrophora. Stężenie buforów i chlorku sodowego, które można uznać za zbliżone do 
izoosmotycznego w stosunku do komórek grzybów (0.0066M), nie zmienia szybkości wzro-
stu szczepów w porównaniu do kontroli. Stężenia dziesięć razy większe spowalniają wzrost, 
szczególnie w stosunku do Z. lanceolata i przy buforze fosforanowym. Silniej hamuje bufor 
fosforanowy niż ftalanowy, co może oznaczać, iż jony fosforanowe zwiększają wrażliwość tych 
grzybów na podwyższone ciśnienie osmotyczne. Stężenie 100 razy większe od izoosmotycz-
nego prawie całkowicie hamuje wzrost, ale w obecności buforu ftalanowego obserwuje się 
znaczną różnicę we wrażliwości między Z. lanceolata a dwoma pozostałymi szczepami, co 
stwarza nadzieję, iż zachowanie się poszczególnych szczepów gatunków z rodzaju Zoophthora 
w obecności podwyższonych stężeń buforów może mieć znaczenie diagnostyczne.



I

III

V

II

IV

VI

1

1

1

1

1

1

2

2

2

2

2

2

3

3

3

3

3

3

Fig. 2A. Morphology and size of the mycelia of Z. aphrophora, Z lanceolata and Z. psyllae on 
media with different concentrations of buffers and NaCl. 



VII

IX

XI

VIII

X

XII

1

1

1

1

1

1

2

2

2

2

2

2

3

3

3

3

3

3

Fig. 2B. Morphology and size of the mycelia of Z. aphrophora, Z. lanceolata and Z. psyllae on 
media with different concentrations of buffers and NaCl. 


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