Trichinella britovi etiological agent of sylvatic trichinellosis in the Republic of Guinea (West Africa) and a re-evaluation of geographical distribution for encapsulated species in Africa

In West Africa, Trichinella infection was documented in humans and animals from Senegal in the 1960s, and the biological characters of one isolate showed a lower infectivity to domestic pigs and rodents when compared with that of a Trichinella spiralis pig isolate from Europe. To identify the Trichinella species present in West Africa, a survey was conducted in a total of 160 wild animals in the Republic of Guinea. Three Viverridae, one true civet (Viverra civetta) and two African palm civets (Nandinia binotata) from the Fouta Djallon Massif, Pilimini Subprefecture, were found positive by artificial digestion of muscle samples. Trichinella larvae from these three viverrids were identified as Trichinella britovi and no difference was detected in three examined sequences from these African isolates and the reference strain of T. britovi from Europe, indicating common ancestry, an historically continuous geographic distribution, and recent isolation for African and European populations. The detection of T. britovi in West Africa modifies our knowledge about the distribution of encapsulated species of Trichinella in Africa. Thus, Trichinella nelsoni is now considered to have a distribution limited to the Eastern part of the Afrotropical region from Kenya to South Africa. This provides a plausible explanation for the presence of Trichinella T8 in Namibia and South Africa, and further suggests that T. britovi could be the Trichinella species circulating among wild animals of Northern Africa.     

How will global climate change affect parasite–host assemblages?

Parasites are integral components of the biosphere. Host switching correlated with events of episodic climate change is ubiquitous in evolutionary and ecological time. Global climate change produces ecological perturbations, which cause geographical and phenological shifts, and alteration in the dynamics of parasite transmission, increasing the potential for host switching. The intersection of climate change with evolutionary conservative aspects of host specificity and transmission dynamics, called ecological fitting, permits emergence of parasites and diseases without evolutionary changes in their capacity for host utilization.     

Invasion status of Florida bass Micropterus floridanus (Lesueur, 1822) in South Africa

Largemouth bass Micropterus salmoides are a popular North American angling species that was introduced into South Africa in 1928. To enhance the largemouth bass fisheries, Florida bass Micropterus floridanus were introduced into KwaZulu Natal, South Africa, in 1980. Knowledge on the status of M. floridanus in South Africa is required, because it lives longer and reaches larger sizes than M. salmoides, which may result in heightened impacts on native biota. Because M. floridanus are morphologically similar, but genetically distinct from M. salmoides, the distribution of this species was assessed by genetically screening 185 Micropterus sp. individuals sampled from 20 localities across South Africa using the mitochondrial ND2 gene. Individuals with mitochondrial DNA matching M. salmoides were recovered from 16 localities, whereas M. floridanus mitochondrial DNA was recovered from 13 localities. At nine localities (45%), the mitochondrial DNA of both species was detected. These results demonstrate M. floridanus dispersal to multiple sites across South Africa.     

Pseudostertagia bullosa (Nematoda: Trichostrongyloidea) in artiodactyl hosts from North America: redescription and comments on systematics

A relationship for Pseudostertagia bullosa within the trichostrongyloids has been enigmatic or unresolved. Studies of the synlophe in males and females of P. bullosa revealed a tapering system anterior to the deirids and a pattern of parallel ridges extending to near the caudal extremity in both lateral and median fields. Structurally, the synlophe differs considerably from that seen among the Cooperiinae and exhibits homoplasy with respect to ridge systems among some Ostertagiinae. Other structural characters due to symplesiomorphy, homoplasy or because they represent autapomorphies do not serve to reveal the putative relationships for P. bullosa with other trichostrongyloids. Although somewhat equivocal, the 2-2-1 pattern of the bursa and position of rays 2 and 3 suggest an association with the Cooperinae, as postulated by Durette-Desset and others. Pseudostertagia bullosa appears to be a species that has survived in the pronghorn, Antilocapra americana, a relictual pecoran artiodactyl that occurs in xeric regions of western North America; pronghorn are the sole remnant of the late Tertiary radiation for Antilocapridae across North America. Pseudostertagia bullosa may occur in mixed infections with a number of ostertagiines in the abomasa of mule deer (Odocoileus hemionus) and domestic sheep (Ovis aries) in regions of sympatry for pronghorn and these artiodactyl hosts.     

Estrogen metabolism as measured in blood and urine in female rhesus monkeys

In order to measure the interconversions of estrone (E1) and estradiol (E2) and their conversion to the 16 alpha-hydroxylated estrogens, 16 alpha-hydroxy estrone (16 alpha-OHE1) and estriol (E3), we infused 11 female rhesus monkeys with [3H]E2 and [14C]E1 and measured radioactivity in the blood as E1, E2 and 16 alpha-OHE1 (n = 9) and in the urine as the glucuronides of E1, E2, 16 alpha-OHE1, and E3 (n = 11). The mean conversion of E1 to E2 as measured in blood (percent of infused E1 measured in blood as E2, [rho]1.2BB) was 29.2 +/- 1.6% and as measured in the urine of the same animals, [rho]1.2BM, was 77.4 +/- 5.9%. The mean conversion of E2 to E1, [rho]2.1BB was 21.5 +/- 1.0% and as measured in urine, [rho]2.1BM was 67.7 +/- 4.6%. Thus for both estrone and estradiol only 30-35% of the interconversions occurred in pools which were in equilibrium with the blood pool of these estrogens. The remaining 65-70% occurred in a pool, probably liver, in which glucuronidation occurred immediately after conversion. The conversion ratios (the ratio of the concentration in the blood of radioactivity as 16 alpha-OHE1 to its precursor, CRPrec,16 alpha-OHE1) was 0.036 +/- 0.008 for CRE1,16 alpha-OHE1 and 0.0039 +/- 0.0010 for CRE2,16 alpha-OHE1. The percentages of administered E1 excreted in the urine as the glucuronides of E1, E2, 16 alpha-OHE1 and E3 were 20.1 +/- 1.5, 1.6 +/- 0.2, 0.96 +/- 0.20 and 0.76 +/- 0.07 respectively. The percentages of administered E2 excreted in the urine as E1, E2, 16 alpha-OHE1 and E3 were 14.4 +/- 1.0, 2.2 +/- 0.3, 0.57 +/- 0.05 and 0.68 +/- 0.11 respectively. Thus there are minor differences in the patterns of excreted metabolites of E1 and E2. Furthermore, 16 alpha-OHE1 and E3 are not major metabolites of E1 or E2 in the female rhesus monkey.     

Host use dynamics in a heterogeneous fitness landscape generates oscillations in host range and diversification

Colonization of novel hosts is thought to play an important role in parasite diversification, yet little consensus has been achieved about the macroevolutionary consequences of changes in host use. Here, we offer a mechanistic basis for the origins of parasite diversity by simulating lineages evolved in silico. We describe an individual‐based model in which (i) parasites undergo sexual reproduction limited by genetic proximity, (ii) hosts are uniformly distributed along a one‐dimensional resource gradient, and (iii) host use is determined by the interaction between the phenotype of the parasite and a heterogeneous fitness landscape. We found two main effects of host use on the evolution of a parasite lineage. First, the colonization of a novel host allowed parasites to explore new areas of the resource space, increasing phenotypic and genotypic variation. Second, hosts produced heterogeneity in the parasite fitness landscape, which led to reproductive isolation and therefore, speciation. As a validation of the model, we analyzed empirical data from Nymphalidae butterflies and their host plants. We then assessed the number of hosts used by parasite lineages and the diversity of resources they encompass. In both simulated and empirical systems, host diversity emerged as the main predictor of parasite species richness.     

Synlophe of Nematodirus neotoma (Trichostrongyloidea)

The synlophe of Nematodirus neotoma from Neotoma spp. is characterized. The cervical synlophe is composed of 30-32 and 36-42 ridges in males and females, respectively. Of these, 14 and 20-22 ridges are continuous in the cervical zone and extend to the base of the cephalic expansion. Six pairs of lateral ridges are discontinuous but extend greater than one-third the length of the cervical region. In both males and females, the number of ridges increases posteriad, terminating near the bursa in the male, and extending the entire length of the body in the female. The synonymy of N. neotoma and N. tortuosus was confirmed.