INDIAN JOURNAL OF PURE & APPLIED BIOSCIENCES

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Indian Journal of Pure & Applied Biosciences (IJPAB)
Year : 2020, Volume : 8, Issue : 6
First page : (124) Last page : (129)
Article doi: : http://dx.doi.org/10.18782/2582-2845.8241

Effect of Arbuscular Mycorrhizal Fungi on the Growth of Mahogany (Swietenia macrophylla King.) Seedlings under Nursery Condition

Satyabrata Nayak1* and Santhoshkumar A.V.2
1Student, 2Professor,
Department of Forest Biology and Tree Breeding, College of Forestry,
Kerala Agriculture University, Vellanikkara, KAU PO, Thrissur, Kerala, India
*Corresponding Author E-mail: satty326@gmail.com
Received: 11.06.2020 | Revised: 18.07.2020 | Accepted: 29.07.2020 

 ABSTRACT

A study was conducted to determine the effect of arbuscular mycorrihzal fungi (AMF) on the growth of Swietenia macrophylla seedlings under nursery condition. It was found that inoculation with AMF at nursery stage can help the plant to grow healthier especially in height and collar diameter. So AMF is recommended to be used as a bio-fertiliser for seedlings at early stage.  These seedlings will tolerate the field plantation shock more effectively than non-inoculated seedlings especially in drought scenario.

Keywords: Mahogany, AMF, Nursery, Bio-fertiliser.

Full Text : PDF; Journal doi : http://dx.doi.org/10.18782

Cite this article: Nayak, S., & Santhoshkumar, A.V. (2020). Effect of Arbuscular Mycorrhizal Fungi on the Growth of Mahogany (Swietenia macrophylla King.) Seedlings under Nursery Condition, Ind. J. Pure App. Biosci. 8(6), 124-129. doi: http://dx.doi.org/10.18782/2582-2845.8241

INTRODUCTION

Swietenia macrophylla King, an important tree species, has been planted extensively in Southern Asia including India, Indonesia, Sri Lanka and Phillipines (Krisnawati et al., 2011). With growing demand of timber farmers tend to add chemical fertilisers during the early stage of growth in the species in a plantation which is harmful to the environment. As an alternative biofertilsers shall be preffered. Arbuscular mycorrihzal fungi (AMF) are associated with about 80% of the terrestrial plant species (Smith & Read, 2008 & Cekic et al., 2012). They help in increasing the biomass of the plants by improving the plant nutrition absorption (especially in phosphorous acquisition), soil structure, resistance against drought and pathogens (Lambers et al., 2008; Walder et al.,2012 & Posada et al., 2018). The tree seedlings when inoculated with AMF in nursery make the healthy and show vigorous growth (Jha et al.,2017). It makes AMF as an excellent bio-fertiliser. The effects of AMF on tree seedlings under nursery condition are well established in Dalbergia sissoo (Sahgal et al., 2004), Populus x Canescens (Beniwal et al., 2010), Fagus sylvatica (Beniwal et al., 2011), Santalum album (Binu et al., 2015) and Tectona grandis (Ajeesh et al., 2017). Studies shows that S. macrophylla naturally found associated with AMF mostly of four genres like Gigaspora, Glomus, Acoulospora and Ambispora (Rodríguez-Morelos et al.,2014).

Considering the fact, an experiment was conducted to analyse the growth of S. macrophylla with association of three AMF species viz. Funneliformis mosseae, Acaulospora mellea, and Glomus etunicatum under nursery condition.

MATERIALS AND METHODS

Site location:
The study site was located at College of Forestry, Kerala Agricultural University, Kerala, India. It has a latitude of 10° 32' N, longitude of 76° 26' E and a 22m elevation from mean sea level (MSL).
Mass multiplication of AMF:
Pure culture of three native AMF species were collected from The Energy Research Institute (TERI), New Delhi containing 500 spores per 50 g. For mass multiplication vermiculite was used for medium, maize (Zea mays) used as host plant and Hogland’s solution added for nutrition (Hogland & Arnon, 1950).
Raising of seedlings:
Seeds of S. macrophylla were sown in polythene bags containing soil which has been fumigated with 5% Formaldehyde.
Inoculation:
Seedlings when reached one month old, then 10 g of AMF inoculum were added (Giri et al.,2005).
Experiment lay-out:
The experiment was laid out in a complete randomized design with three treatments and control with three replications each.
Observation:
Shoot height, collar diameter and number of leaves, root colonisation percentage and total spore count was recorded in nursery. The root colonisation percentage was estimated using clearing and staining method by Phillips and Hayman (1970) and spore count was done using wet sieving and decanting method by Gerdemann and Nicolson (1963).

RESULTS

Table 1: Meteorological observations during the experiment


Year

Month

Maximum temperature (°C)

Minimum temperature (°C)

Rainfall (mm)

Relative humidity (%)

Mean evaporation (mm)

Number of Rainy days

2016

October

31.5

22.7

37.0

81

2.8

4

November

32.9

22.2

13.8

69

3.0

1

December

32.4

22.3

52.9

69

3.3

3

Table 2: Shoot height, collar diameter and number of leaves of mahogany seedlings as influenced by AMF under nursery conditions at 30 days of inoculation


Treatments

Height (cm)

Collar diameter (mm)

Number of leaves

F. mosseae

16.75

1.54a

5.94

A. mellea

17.13

1.66a

6.23

G. etunicatum

16.78

1.54a

6.02

Control

14.21

1.31b

6.06

F value

2.377ns

12.216*

0.434ns

CoV

9.351

4.739

5.27

*-Significant at 5% level, ns – Non-significant at 5% level

Table 3: Shoot height, collar diameter and number of leaves of mahogany seedlings as influenced by AMF under nursery conditions at 60 days of inoculation


Treatments

Height (cm)

Collar diameter (mm)

Number of leaves

F. mosseae

23.14

2.45a

6.95

A. mellea

24.11

2.38ab

6.85

G. etunicatum

23.66

2.34b

6.49

Control

19.97

2.07c

6.90

F value

3.56ns

34.033*

1.941ns

CoV

7.57

2.150

3.802

*-Significant at 5% level, ns – Non-significant at 5% level

Table 4: Shoot height, collar diameter and number of leaves of mahogany seedlings as influenced by AMF under nursery conditions at 90 days of inoculation


Treatments

Height (cm)

Collar diameter (mm)

Number of leaves

F. mosseae

30.59a

3.66a

9.07

A. mellea

31.28a

3.61a

9.68

G. etunicatum

31.21a

3.70a

8.92

Control

26.28b

3.22b

8.71

F value

5.067*

13.195*

1.611ns

CoV

6.17

3.003

6.295

*-Significant at 5% level, ns – Non-significant at 5% level

Table 5: Root colonisation percentage leaves of mahogany seedlings as influenced by AMF under nursery conditions


Treatments

Root colonisation percentage (%)

30 days

60 days

90 days

F. mosseae

27.2

23.2

35.68

A. mellea

23.5

29.6

35.5

G. etunicatum

28.7

23.6

39.15

Control

0

0

0

Mean

26.46

25.46

36.77

Table 6: Root colonisation percentage leaves of mahogany seedlings as influenced by AMF under nursery conditions


Treatments

Total spore count (per 10 g)

30 days

60 days

90 days

F. mosseae

59

71

101

A. mellea

54

71

96

G. etunicatum

51

59

95

Control

0

0

0

Mean

54.66

67

97.33

 

DISCUSSION

The selection of AMF species was done on the soil type and AMF species diversity of the soils of Kerala. The soils of Kerala  is well drained sandy clay loam Ultisol (Raj et al., 2016) and predominantly home of AMF genus Glomus and Acaulospora (Gopal et al., 2005). The AMF have the ability to reach beyond root expansion zone of plant and get water and nutrients for the plant (Smith & Read 2008). So plants which have been inoculated with AMF have maore access towards nutrients and can grow vigorously. The present study showed that seedlings with AMF inoculation have positive impact on their growth than the non-inoculated seedlings. However, different AMF species had similar impact on the growth of the seedlings. There was a significant increase in height of inoculated seedlings at 90 days comparing to the non-inoculated seedlings. The collar diameter of inoculated seedlings was significantly higher than the non-inoculated seedlings. Similar result has been reported in different tree species like Dalbergia sissoo (Sahgal et al., 2004), Acacia mangium (Ghosh & Verma 2006 & Jeyanny et al., 2011), Casuarina equisetifolia (Zhang et al., 2010), Prunus persica (Wu et al., 2011), Fagus sylvatica (Beniwal et al., 2011), Citrus spp (Ortas & Usttuner 2014), Santalum album (Binu et al., 2015) and Tectona grandis (Ajeesh et al., 2017). However, the leaf numbers don’t vary significantly which may be due to the early stage of growth (Querejeta et al., 1998). The root colonisation percentage and spore count can vary from 4 to 95% (Birhane et al., 2018). The root colonisation percentage and total spore count was found moderate in this experiment. As the result indicates it is recommended to add AMF inoculant applied at the early stage of seedlings will make them healthy and will withstand transplantation shock easily.


CONCLUSION

S. macrophylla seedlings showed a significant increase in growth performance when inoculated with AMF under nursery condition. So AMF can be used as an alternative of chemical fertiliser which definitely help in reducing the environmental pollution.


Acknowledgement

The authors wish to thank faculties and staffs of College of Forestry, Kerala Agricultural University for the technical support.


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