Recombination dynamics of human parechoviruses: investigation of type-specific differences in frequency and epidemiological correlates.

Human parechoviruses (HPeVs) are highly prevalent RNA viruses classified in the family Picornaviridae. Several antigenically distinct types circulate in human populations worldwide, whilst recombination additionally contributes to the genetic heterogeneity of the virus. To investigate factors influencing the likelihood of recombination and to compare its dynamics among types, 154 variants collected from four widely geographically separated referral centres (UK, The Netherlands, Thailand and Brazil) were typed by VP3/VP1 amplification/sequencing with recombination groups assigned by analysis of 3Dpol sequences. HPeV1B and HPeV3 were the most frequently detected types in each referral region, but with marked geographical differences in the frequencies of different recombinant forms (RFs) of types 1B, 5 and 6. HPeV1B showed more frequent recombination than HPeV3, in terms both of evolutionary divergence and of temporal/geographical indicators of population separation. HPeV1 variants showing between 10 and 20% divergence in VP3/VP1 almost invariably fell into different recombination groups, compared with only one-third of similarly divergent HPeV3 variants. Substitution rates calculated by beast in the VP3/VP1 region of HPeV1 and HPeV3 allowed half-lives of the RFs of 4 and 20 years, respectively, to be calculated, estimates fitting closely with their observed lifespans based on population sampling. The variability in recombination dynamics between HPeV1B and HPeV3 offers an intriguing link with their markedly different seasonal patterns of transmission, age distributions of infection and clinical outcomes. Future investigation of the epidemiological and biological opportunities and constraints on intertypic recombination will provide more information about its influence on the longer term evolution and pathogenicity of parechoviruses.

Morphologic and functional alterations in absorptive epithelial cells during L-tryptophan induced inhibition of net sodium and fluid absorption in the rat ileum.

L-Tryptophan (L-Trp) has been reported to suppress jejunal fluid and electrolyte transport in vitro, at a 20 mM concentration, whereas other amino acids enhance that absorption at the same concentration. The effect of L-Trp, glycine (Gly) and L-phenylalanine (L-Phe) on in vivo ileal and jejunal fluid and sodium transport, and their morphologic correlates, were investigated in the rat. In the ileum, morphology as well as fluid and sodium transport were more readily altered by L-Trp than in the jejunum. The ileal effects were rapid; morphologic and transport changes were seen within 2.5 minutes. The changes were stereospecific; they occurred only with the levo, but not with the dextro isomer of Trp. There was a concentration dependence; 20 mM levels of L-Trp were required, whereas lower concentrations of the amino acid often stimulated net absorption. Morphologic alterations produced by L-Trp were restricted to absorptive epithelial cells, whereas goblet cells appeared unaffected. Morphologically, L-Trp treatment led to the formation of clear basal vacuoles in ileal absorptive epithelial cells at 2.5 minutes, and extensive vacuolization and loss of the lumenal permeability barrier to macromolecules at 30 minutes. Since L-Trp can be hydroxylated in the small intestine, we assessed the effects of L-5 = OH tryptophan and 5-hydroxytryptamine on small intestinal transport and morphology in this experimental system. L-5-OH tryptophan inhibited fluid transport and produced some epithelial cell vacuolization. However, 5-hydroxytryptamine, which most severely decreased transport, had none of the morphologic effects of L-Trp. We hypothesize that L-Trp may inhibit transport as a result of its intracellular accumulation in absorptive epithelial cells.

Quantitative alterations in the structural development of jejunal absorptive epithelial cells and their subcellular organelles in protein-energy-malnourished rats: a stereologic analysis.

The effect of protein-energy malnutrition (PEM) on the structural development of rat jejunal absorptive epithelial cells was evaluated. Stereologic characteristics of jejunal histologic subcompartments, epithelial cell surfaces and volumes, and volumes of key subcellular organelles (nuclei, mitochondria, Golgi apparatus, lysosomes) in crypt and villus mid and tip cells were determined by morphometric analysis of light and electron micrographs in well-nourished rats and rats with PEM. In rats with PEM there were developmental alterations in cells migrating on villi that were not seen in crypt cells. The amplification of the apical microvillus surface between mid and tip levels in well-nourished rats (679-1085 micron2/cell) failed to occur in rats with PEM (807-729 micron2/cell). This resulted in an estimated 60% reduction of total jejunal absorptive surface, from 10,070 cm2 in well-nourished rats to 3975 cm2 in rats with PEM. In contrast, the development of the basolateral surface, which requires much less membrane accrual, was unaffected by PEM. Villus mid and tip cells of rats with PEM also had increased cell volume and mitochondrial volumes. Microvillus surface area per cell appears dependent on the number of microvilli per cell, which equals the cell flat surface times the microvillus numerical density (number of microvilli per square micrometer) in well-nourished rats. However, this relationship was not demonstrable in rats with PEM.