Cuticle heterogeneity as exhibited by Pasteuria spore attachment is not linked to the phylogeny of parthenogenetic root-knot nematodes (Meloidogyne spp.).

The cuticle is a major barrier prohibiting the infection of nematodes against micro-organisms. The attachment of bacterial spores of the nematode hyperparasite Pasteuria penetrans (PP1) to field populations of root-knot nematodes (RKN, Meloidogyne spp.) from Burkino Faso, Ecuador, Greece, Malawi, Senegal and Trinidad and Tobago were assayed in standard attachment tests. The attachment of spore population PP1 to different field populations of root-knot nematode showed that the rates of attachment differed between countries. Similar tests were also undertaken on P. penetrans spores from these countries against 2 species of RKN, M. incognita and M. arenaria. The results showed a high degree of variability in spore attachment with no clear distinction between the 2 species of nematode. It has been hypothesized that Pasteuria spore attachment is linked to nematode species designations and this study clearly shows that this is not the case. Further tests showed that variation in spore attachment was not linked to nematode phylogeny. The results therefore beg the question of how do parthenogenetic root-knot nematodes maintain cuticle variability in the face of such an aggressive hyperparasite.

Comparison of Sequences from the Ribosomal DNA Intergenic Region of Meloidogyne mayaguensis and Other Major Tropical Root-Knot Nematodes.

The unusual arrangement of the 5S ribosomal gene within the intergenic sequence (IGS) of the ribosomal cistron, previously reported for Meloidogyne arenaria, was also found in the ribosomal DNA of two other economically important species of tropical root-knot nematodes, M, incognita and M. javanica. This arrangement also was found in M. hapla, which is important in temperate regions, and M. mayaguensis, a virulent species of concern in West Africa. Amplification of the region between the 5S and 18S genes by PCR yielded products of three different sizes such that M. mayaguensis could be readily differentiated from the other species in this study. This product can be amplified from single juveniles, females, or egg masses. The sequences obtained in this region for one line of each of M. incognita, M. arenaria, and M. javanica were very similar, reflecting the close relationships of these lineages. The M. mayaguensis sequence for this region had a number of small deletions and insertions of various sizes, including possible sequence duplications.

Molecular and Biochemical Diversity Among Isolates of Radopholus spp. from Different Areas of the World.

Eleven isolates of Radopholus similis from various banana-growing areas around the world and one isolate of R. bridgei from turmeric in Indonesia were compared using DNA and isoenzyme analysis. The polymerase chain reaction (PCR) was used to amplify a fragment of ribosomal DNA (rDNA), comprising the two internal transcribed spacers (ITS) and the 5.8S gene. Restriction fragment length polymorphisms (RFLPs) in this rDNA fragment were used to compare the 10 isolates. The analysis of this rDNA region revealed little variation among the isolates tested. However, data also were obtained by random amplified polymorphic DNA (RAPD) analysis of total DNA, and a hierarchical cluster analysis of these data arranged the R. similis isolates into two clusters. The first cluster consisted of isolates from Nigeria, Cameroon, Queensland, and Costa Rica; the second was comprised of isolates from Guinea, Guadeloupe, the Ivory Coast, Uganda, and Sri Lanka. The isolate of R. bridgei from turmeric in Indonesia appeared to be more divergent. This grouping was consistent with that obtained when phosphate glucose isomerase (PGI) isoenzyme patterns were used to compare the R. similis isolates. The results from both RAPD analysis and PGI isoenzyme studies indicate that two gene pools might exist within the R. similis isolates studied. No correlation could be detected between the genomic diversity as determined by RAPD analysis and either geographic distribution of the isolates or differences in their pathogenicity. The results support the hypothesis that R. similis isolates have been spread with banana-planting material.