Meloidogyne minor

 

Contents

 

Rev 10/24/2023

  Classification Hosts
Morphology and Anatomy Life Cycle
Return to Meloidogyne Menu Economic Importance Damage
Distribution Management
Return to Heteroderidae Menu Feeding  References
    Go to Nemaplex Main Menu   Go to Dictionary of Terminology

Classification:

      Tylenchida
       Tylenchina
        Tylenchoidea
         Heteroderidae
          Meloidogyninae

           Meloidogyne minor Karssen, Bolk, Van Aelst, Van Den Beld, Kox, Korthals, Molendijk, Zijlstra, Van Hoof & Cook, 2004

  Review general characteristics of the genus Meloidogyne.

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Morphology and Anatomy:

 

  Female: 
  Mature Female:  Body morphology.
  Perineal pattern
   
Male:  Male: 

Reported median body size for this species (Length mm; width micrometers; weight micrograms) - Click:

Second-stage juvenile

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Distribution:

Meloidogyne minor has been found primarily on golf courses and sports fields in the Netherlands, Belgium, United Kingdom, Ireland and the United States (Washington State) (Elling, 2013).

It also occurs in coastal dunes in Europe and there is concern that it is spreading throughout northwest Europe.

Easily spread through sod that is brought in and rolled out rather than planted as seed.

It could easily be spread by contamination of  footwear and sports equipment.

Due to the risk of spread, the European and Mediterranean Plant Protection Organisation (EPPO) has placed M. minor on its alert list (Elling, 2013).

 

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Economic Importance:

Yellow patches on golf greens constructed on sandy soils pwer USGA guidelines.

Meloidogyne minor is copnsidered a serious threat to turfgrass in north-west Europe, and has a broad host range that includes other economically important plants (Morris et al., 2011)..

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Feeding:

Sedentary endoparasite.

Feeding site establishment and development typical of genus.

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Hosts:

Type Hoste: potato (Solanum tuberosum)

Meloidogyne minor could spread to agronomic crops as its host range includes carrots, alfalfa, oat, lettuce, and tomato under greenhouse conditions.  It reproduces on potato roots and tubers under field conditions (Elling, 2013).

Under field conditions, the nematode failed to reproduce on sugar beet, maize, and rye .

For an extensive host range list for this species, click

 

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Life Cycle:

Ecophysiological Parameters:

For Ecophysiological Parameters for this species, click If species level data are not available, click for genus level parameters

Haploid chromosome number n=17; reproduction is by facultative meiotic parthenogenesis. The egg nucleus undergoes a meiotic reduction division; one member of each pair of chromatids remains in a haploid nucleus and the other in a polar body. If fertilization by a male sperm occurs, the diploid number of chromosomes is restored. Otherwise the somatic number of chromosomes is restored by fusion of the egg pronucleus with the polar body from the reduction division (Subbotin et al., 2021; Triantaphyllou, 1985).

Eggs were present throughout the year in a golf green sown with creeping bentgrass (Agrostis stolonifera var. stolonifera L). There was a high percentage hatch (46-88%) when eggs were incubated at 20◦C. Egg development and hatch ocurred at tempreatures between 15 and 25C and was very limited above and below that range, It was most rapid at 23C (7 days)  and slower at 15C (17 days). (Morris et al., 2011).

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Damage:

Causes yellow-patches within a few years after new greens have been established (Elling, 2013; Morris et al., 2011).

Symptoms on potato are very similar to those of M. chitwoodi and M. fallax, i.e., small galls in roots and pimple-like swellings on the surface of potato tubers.  However, M. fallax did not reduce yield or quality on two potato cultivars tested in the Netherlands (Elling, 2013).

 

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Management:

Host Plant Resistance, Non-hosts and Crop Rotation alternatives:

For plants reported to have some level of resistance to this species, click
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References:

Elling, A.A. 2013. Major Emerging Problems with Minor Meloidogyne Species. Phytopathology 103:1092-1102.

Karssen, G., Bolk, R. J., Van Aelst, A. C., Van Den Beld, I., Kox, L. F. F., Korthals, G., Molendijk, L., Zijlstra, C., Van Hoof, R., and Cook, R. 2004. Description of Meloidogyne minor n. sp. (Nematoda: Meloidogynidae), a root-knot nematode associated with yellow patch disease in golf courses. Nematology 6:59-72.

Morris, K.S., Horgan, F.G., Downes, M.J., Griffin, C.T. 2011. The effect of temperature on hatch and activity of second-stage juveniles of the root-knot nematode, Meloidogyne minor,
an emerging pest in north-west Europe. Nematology 13:983-993.

Subbotin, S.A. Palomares-Rius, J.E., Castillo, P. 2021. Systematics of Root-knot Nematodes (Nematoda: Meloidogynidae). Nematology Monographs and Perspectives Vol 14: D.J. Hunt and R.N. Perry (eds) Brill, Leiden, The Netherlands 857p.

Triantaphyllou, A.C. 1985. Gametogenesis and the chromosomes  of Meloidogune nataliei: not typical of other root-knot nematodes. J. Nematology 17:1-5.

Triantaphyllou, A.C. 1985. Cytogenetics, cytotaxonomy and phylogeny of root-knot nematodes. In Sasser, J.N. & Carter, C.C. (eds) An Advanced Treatiswe on Meloidogyne.Vol 1. Biology and Control.N.C. State Universty Graphics, Raleigh, N.C. USA.

 

 
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Copyright © 1999 by Howard Ferris.
Revised: October 24, 2023.