Unveiling the potential of Trichoderma harzianum against Heterodera cajani in pigeon pea: impact on cysts, egg and juveniles abundance

Background

Pigeon pea is affected by the cyst nematode Heterodera cajani limiting the production. H. cajani can be managed by biological agents such as Trichoderma harzianum. Thus, the determination of this experiment was to estimate native strains of T. harzianum isolated from pigeon pea fields in India on population of cyst, eggs and juveniles of H. cajani. Pots experiment was conducted at the playhouse of Sam Higginbottom University of Science and Technology, Prayagraj (UP), India, during the year of 2018–2020. Earthen pots were filled with sterilized soil @ 10 kg/pot for each replicate of the treatments. Ten days before sowing of the pigeon pea seed, about 5000 spores of T. harzianum were amended in to the soil for proper colonization. Fifteen days after seed germination, 200 cysts/pot were inoculated near the root zone of pigeon pea plant. The pots were irrigated when required. Observations were recorded of cyst population, eggs and second juveniles of H. cajani/500gm of pigeon pea rhizospheric soil at 90 days after sowing.

Results

Among all the isolates of T. harzianum, the treatment (T 7) reduced of cyst population (12), eggs population (234) and juveniles’ population (153) as compared with all other treatments including control at 90 days after sowing of pigeon pea seeds in the year 2018–2019. Similarly, in 2019–2020 reduction in cyst population (11), eggs population (189) and juveniles population (160) was observed at 90 days after sowing in Trichoderma isolates (T 7) as compared to control.

Conclusions

The findings of this study are very relevant since seven isolates of native T. harzianum were promising to suppress the number of cysts in 79.31 and 83.07%, eggs in 22.00 and 38.83% and juveniles’ population in 17.74 and 20.39% of the nematode H. cajani, besides promoting the pigeon pea plant growth.

The pigeon pea (Cajanus cajan L.), which ranked sixth internationally behind peas, broad beans, lentils, chickpeas and common beans, is farmed on 5.4 million hectares of land worldwide and produces 4.49 million metric tons annually (Fatokimi and Tanimonure 2021). More than 100 pathogens attack this crop including nematodes, fungus, viruses, bacteria and MLOs (Reddy 2021). Significant damage to the crop at all stages is caused by plant parasitic nematodes which are microscopic (Maurya et al. 2020a). Pest causes up to 50% of potential crop loss, while 12.3% is supposed to be caused by nematodes and more damage to the crops due to nematode infestation is detected in the emerging countries than in the industrialized countries (Carneiro et al. 2017). Scientists have become interested in plant parasitic nematodes since they have been linked to significant, widespread diseases. There are many genera and species of plant parasitic nematodes that reduce the quality and quantity of yields in different crops while also raising the price of production. The crop of pigeon peas suffers significant damage from plant parasitic nematodes, which causes the plants' physiological processes to malfunction, lowering crop yield. The cyst nematode H. cajani has been shown to live on pigeon pea, and this parasite is by far the most prevalent (Briar et al. 2023). According to Ali and Askary (2001), H. cajani is among the most significant pests of pigeon pea in India, along with M. incognita, M. javanica and R. reniformis. According to Abd-Elgawad and Askary (2015), plant parasitic nematodes are responsible for a 13.2% yearly output loss in pigeon pea production globally. Adult females of H. cajani can be identified by their lemon-shaped forms, short necks and terminal cones. The cysts initially have a light yellow tint, but over time, they form strong walls, progress from yellow to brown to black, and eventually turn entirely black. H. cajani females are very different from females of other species. Their huge egg sac, which can occasionally be nearly twice as big as the cyst itself, is a distinguishing feature of these growths (Ali and Singh 2005). Edward and Misra (1968) reported H. vigni from the roots of pigeon pea (Vigna unguiculata), which was later discovered to be synonymous with H. cajani.

The use of Trichoderma harzianum as a biological control has been very effective in sustainable agricultural systems. The fungus is effective in controlling nematodes such as Heterodera (genera) by colonizing and trapping them (Tylka and Marett 2022), reducing disease through the predation of nematodes (Maina et al. 2022), its nematotoxic effects (Mhatre et al. 2022) and inhibiting egg hatching and juvenile mortality (Kumar et al. 2020). Therefore, the purpose of this investigation was to assess the effects of local T. harzianum strains found in Indian pigeon pea fields on the population of cysts, eggs and juveniles of Heterodera cajani.

Trichoderma harzianum—isolation, purification and identification

The process of isolation of T. harzianum was made from the rhizosphere of a healthy pigeon pea plant in the region of Prayagraj, UP in 10 different fields. The soil in the 10-cm rhizosphere was carefully scraped out from around the roots, which were then sliced into little pieces and mixed with the soil. T. harzianum were isolated using the serial dilution plate method (Sharma et al. 2019). The conidium morphology of T. harzianum can be used to quickly identify them. This species can be distinguished from all other T. harzianum by its small, subglobose conidia, which are typically 2–3 to 1.5–2.5 m in size. Conidiophores have a pyramidal, verticillate branching structure and lack a sterile apical elongation at maturity, despite the fact that developing conidiophores may show a visible sterile extension in the early stages of growth.

Collection, processed and identification of cyst nematode from infested soil

Infected soil was collected from different fields and processed by sieve methods. In this processing, 500 g of infested soil was passed through 25 mesh and then 60 mesh, the cyst of Heterodera (Da Silva Café and Santos 2023) cajani cannot pass through 60 mesh thus were collected carefully. The nematode suspension was stirred and poured in a small quantity in the counting dish. The counting dish was rotated under the low-power binocular microscope in search of cyst nematode. When the cyst appeared into the field, they were identified. The cysts were counted by using the counter and collected into the cavity block with the help of forceps (Maurya et al. 2022b) (Fig. 1). The female cyst is lemon shaped. The cuticle is marked by thick, zigzag lines. One large and one smaller annule is present on the head region (Koshy 1967). Cowpea seeds were sown for the mass multiplication of H. cajani in pot (Fig. 2).

Morphological identification of cyst nematode (Heterodera cajani), A Females of cyst nematode; B Hatching juveniles from egg of cyst

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Mass multiplication of Heterodera cajani

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Experimental site

Pots experiment was conducted at the playhouse of Sam Higginbottom University of Science and Technology, Prayagraj (UP), India, during the year of 2018–2020. Prayagraj was 98 masl and was sited at 25.27 levels north and 81.50 ranged east. Commonly, the climate is subtropical and semiarid. In the summer season, the maximum temperature might also get as excessive as 46.5 °C, and in the winter, it can reach up to 1.5 °C. Approximately, 1100 mm of rain precipitation takes place annually on common.

Preparation of treatments

The earthen pots were used for the experiment. The experiment's pots were washed in running water. The soil was collected and sterilized with 1% formalin solutions, earthen pots were filled with sterilized sandy loam soil @ 10 kg/pot for each replicate of the treatments. Before sowing the seed, about 5000 spores of T. harzianum (calculated by hemocytometer) were amended into the 10 kg of soil for proper colonization. Ten days after amendments of T. harzianum, seeds of pigeon pea (Upaas variety) were sown in each pot. In control pots, soil without amendment and one chemical (Carbofuran) were maintained for comparison. Fifteen days after seed germination, 200 cysts/ pot were inoculated near the root zone of pigeon pea plant. The pots were irrigated when required. Observations were recorded of cyst population, eggs and second juveniles of H. cajani (Min et al. 2020)/500gm of pigeon pea rhizospheric soil at 90 days after sowing.

Data analysis

A completely randomized design (CRD) was employed as the experimental design with three replications. A design of freedom (df) that was appropriate was created using the calculated value of F at a 5% level of probability (Chandel 2010; Abd-Elgawad 2021). Data expressed as percentages were transformed according to the angular transformation.

First year (2018–2019)

The evaluation of T. harzianum on cyst, eggs and juveniles population in pigeon pea root and rhizospheric (500 g) soil was carried out. The result (Table 1 and Fig. 3) of the year 2018–2019 indicated that, at 90 days, T. harzianum isolates notably reduced the number of cyst population in the roots of pigeon pea plants as compared to control (nematode alone) (58). The maximum reduction of cyst population was recorded in T₁₁ (Carbofuran 6), T₇ (12) and T₁ (17), followed by T₉ (20), T₆ (21), T₁₀ (22). The minimum reduction of cyst population was recorded in T₃ (37) and T₂ (34), followed by T5 (31), T4 (29) and T8 (25). The maximum reduction of egg population per cyst nematode female was also found in T₁₁ (Carbofuran 197), T₇ (234), followed by T₁ (242), T₃ (243), T₄ (245). The minimum reduction of egg population was recorded in T₆ (292) and T₅ (292), followed by T₈ (270), T2 (264), T9 (252) and T10 (249).

Evaluation the isolates of Trichoderma harzianum on cyst population, eggs and juveniles of Heterodera cajani/500 g of pigeon pea rhizospheric soil (2018–2019)

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The juveniles population/female cyst was also counted and it was observed that all isolates of the T. harzianum notably reduced the juveniles population of H. cajani in T₁₁ (Carbofuran 135), followed by T₇ (153) T₃ (155), T₂ (158), T₁ (161) and T₈ (161). The minimum reduction of juveniles population in T₄ (179), followed by T5 (169), T6 (167), T9 (166) and T10 ( 165).

Second year (2019–2020)

The result (Table 2 and Fig. 4) of the year 2019–2020 indicated that at 90th day, all the isolates of T. harzianum significantly reduced the number of cyst population in the roots of pigeon pea plants as compared to control (nematode alone) (65). The maximum reduction of cyst population was recorded in T₁₁ (Carbofuran 7), T₇ (11) and T₁ (14), followed by T₉ (19), T₆ (20), T₈ (21) and T₁₀ (21). The minimum reduction of cyst population was recorded in T₃ (36) and T₂ (32), followed by T₅ (29) and T₄ (27).

Evaluation the isolates of Trichoderma harzianum on cyst population, eggs and juveniles of Heterodera cajani/500 g of pigeon pea rhizospheric soil (2019–2020)

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Each isolate of T. harzianum effectively reduced the eggs population of H. cajani than the control (309). The maximum reduction of egg population per cyst nematode female was also found in T₇-(T 189) and T₁₁ (Carbofuran 193), followed by T₁ (235), T₃ (T 235), T₄ (T 239), T₁₀ (241) and T₉ (243). The minimum reduction of egg population was recorded in T₅ (290) and T₆ (284), followed by T₈ (259) and T₂ (255).

Each isolate of T. harzianum suppressed the number of juveniles’ population of H. cajani than the control (201). The maximum number of juveniles population /female cyst was counted and observed that all isolates of T. harzianum significantly suppressed the juveniles colony of H. cajani in T₁₁ (Carbofuran 133), T₈ (144), T₃ (146), T₂ (147), followed by T₁₀ (153) and T₉ (158). The minimum reduction of juveniles population in T₁ (183) and T₄ (170), followed by T₅ (164), T₇ (160) and T₆ (160).

Conidiophores of T. harzianum have a pyramidal, verticillate branching structure and lack a sterile apical elongation at maturity, despite the fact that developing conidiophores may have a visible sterile extension in the early stages of growth. Ten distinct isolates of T. harzianum were collected and kept. The biocontrol agents of Pochonia chlamydosporia recorded 60.96 cyst populations as compared to 69.3 by T. harzianum, which was reported by Sinha et al. (2018). Similar work was performed by Sangma et al. (2022) where the antagonistic potential of T. harzianum was estimated in contradiction of Heterodera cajani of Cajanus cajan for 3 years. The solicitation of T. harzianum at 5 kg/ha significantly reduced the cyst nematode population (52.73) (Kalita 2020). Sinha et al. (2018) reported that maximum reduction in cyst nematode (H. cajani) multiplication was found in pigeon pea when G. mosseae, T. harzianum and P. chlamydosporia were used together. Use of T. viride reduced by the incidence of H. cajani on green gram, red gram and black gram (Alase et al. 2020). According to Carneiro et al. (2017), Trichoderma spp. had also been shown to colonize Globodera rostochiensis eggs and juveniles and devour the egg contents (Krif et al. 2020). Trichoderma spp. mineralize phosphorus in soil containing fungi (Guzmán-Guzmán et al. 2023). Sikora et al. (2021) stated that enzymes or other chemicals produced by fungi prevent the development of Meloidogyne and Heterodera in the rhizosphere in cooperation with the plant's root system. In order to offer significant information regarding these bioagents' effectiveness in controlling G. rostochiensis in the field, more research is required (Singh 2022). The bioagents Fusarium spp., Trichoderma spp., B. thuringiensis and Saccharopolyspora spinosa may cause a drop in nematode levels at the rates utilized in this experiment and may serve as a replacement control alternative to suppress Meloidogyne sp., G. rostochiensis. G. rostochiensis' growth was significantly inhibited by Trichoderma species. Reproduction rates dropped by 36.0–44.4% for both fungi and bacterial preparations by 27.7–33.3% than the controls (Mhatre et al. 2022). The findings of this study are very relevant since seven isolates of native T. harzianum are promising candidates to suppress the number of cysts, eggs and juveniles population of the phytopathogen nematode H. cajani, in addition to promote plant growth.

Seven isolates of the fungus T. harzianum are promising candidates to reduce the population of the nematode H. cajani's juveniles by 17.74 and 20.39%, eggs by 22.00 and 38.83%, and cysts by 79.31 and 83.07%. The level of 5000T. harzianum spores in 10 kg of soil had the capacity to reduce the number of H. cajani cysts, eggs and juveniles. The pigeon pea plant can grow more quickly thanks to T. harzianum. These local Trichoderma isolates can be regularly employed to control plant pathogenic nematodes that harm legumes.

All data are available at the end of the article and the materials used in this work are of high quality and grade.

• 02 February 2024

  A Correction to this paper has been published: https://doi.org/10.1186/s41938-024-00773-9

%:

Percent

/:

Per

@:

At the rate of

°C:

Degree centigrade

ANOVA:

Analysis of variance

C f u:

Colony forming units

cm:

Centimeter

CD:

Critical difference

DAS:

Days after sowing

d.f.:

Degree of freedom

ESS:

Error sum of square

et al. :

And others

etc.:

And the rest

F (tab.):

Tabulated value of F

F (cal.):

Calculated value of F

gm:

Gram

hrs.:

Hours

i.e.:

That is

MSS:

Mean sum of square

TSS:

Total sum of square

ml.:

Milliliter

spp.:

Species

viz.:

Namely

T. s.:

Trichoderma Spp

F.o.c.:

Fusarium udum

H. c.:

Heterodera cajani

CRD:

Completely randomized design

T:

Treatment

Head of Department of Plant Pathology, SHUATS, Prayagraj, U. P., authorities for providing me all the facilities to successful completion of this research work. Prince Sattam Bin Abdulaziz University project number (PSAU/2024/R/1445).

Significant statement

This study is particularly beneficial to nematologists and plant pathologists since it offers significant details about the control of Heterodera cajani by Trichoderma harzianum on pigeon pea (Cajanus cajan L.) grown in a playhouse system.

Not applicable.

Authors and Affiliations

1. School of Agricultural Sciences, IIMT University, Meerut, 250001, Uttar Pradesh, India

   Amit Kumar Maurya & Harish Kumar

2. Department of Agriculture, Ghanshyam Urvashi P.G College, Phoolpur, Prayagraj, 211002, Uttar Pradesh, India

   Vinny John

3. Department of Zoology, C. M. P. P. G. College, Prayagraj, 211002, Uttar Pradesh, India

   Hemlata Pant

4. Council of Science & Technology, Vigyan Bhawan, Lucknow, 226018, Uttar Pradesh, India

   D. K. Srivastava

5. Department of Plant Protection, Faculty of Agriculture, Benha University, Benha, 13736, Qalyubia, Egypt

   Nevin Ahmed

6. Department of Medical Laboratory Sciences, Faculty of Applied Medical Sciences, King Abdulaziz University, Jeddah, 21589, Saudi Arabia

   Fadi Baakdah

7. Special Infectious Agents Unit, King Fahd Medical Research Center, King Abdulaziz University, Jeddah, 21589, Saudi Arabia

   Fadi Baakdah

8. Department of Food Science and Nutrition, College of Sciences, Taif University, P.O. Box 11099, Taif, 21944, Saudi Arabia

   Rokayya Sami

9. Department of Biology, College of Science, Taif University, P.O. Box 11099, Taif, 21944, Saudi Arabia

   Alaa Baazeem

10. Department of Biology, College of Science and Humanities in Al-Kharj, Prince Sattam Bin Abdulaziz University, Al-Kharj, 11942, Saudi Arabia

    Abeer Elhakem

11. Department of Clinical Laboratory Sciences, College of Applied Medical Sciences, King Khalid University, P.O. Box 960, Abha, 61421, Saudi Arabia

    Mohammad Y. Alshahrani

12. Department of Biology, Al-Jumum University College, Umm Al-Qura University, Makkah, 21955, Saudi Arabia

    Alaa T. Qumsani & Sameer H. Qari

Contributions

The experiments were run and the paper was written by AKM. The information was evaluated and processed by VJ, DKS, NA and FB. The work was organized by HP, RS, AB, and AE, MYA. The manuscript was looked at and modified by HK, SHQ and ATQ. For final submission. The work was read and approved by all authors.

Corresponding authors

Correspondence to Amit Kumar Maurya or Rokayya Sami.

Ethics approval and consent to participate

There are no researches conducted on animals or humans.

Consent for publication

The agreement of publication was taken.

Competing interests

The authors declare that they have no competing interests.

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The original online version of this article was revised: "Following publication of the article, the authors flagged that affiliation 11 was incomplete: 'King Khalid University' had been erroneously omitted from the affiliation. The affiliation has since been corrected in the published article. The authors thank you for reading this erratum.

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