Global view on virus infection in non-human primates and implications for public health and wildlife conservation.

Viruses can be transmitted from animals to humans (and vice versa) and across animal species. As such, host-virus interactions and transmission have attracted considerable attention. Non-human primates (NHPs), our closest evolutionary relatives, are susceptible to human viruses and certain pathogens are known to circulate between humans and NHPs. Here, we generated global statistics on VI-NHPs based on a literature search and public data mining. In total, 140 NHP species from 12 families are reported to be infected by 186 DNA and RNA virus species, 68.8% of which are also found in humans, indicating high potential for crossing species boundaries. The top 10 NHP species with high centrality in the NHP-virus network include two great apes (Pan troglodytes, Pongo pygmaeus) and eight Old World monkeys (Macaca mulatta, M. fascicularis, M. leonina, Papio cynocephalus, Cercopithecus ascanius, C. erythrotis, Chlorocebus aethiops, and Allochrocebus lhoesti). Given the wide distribution of Old World monkeys and their frequent contact with humans, there is a high risk of virus circulation between humans and such species. Thus, we suggest recurring epidemiological surveillance of NHPs, specifically Old World monkeys that are in frequent contact with humans, and other effective measures to prevent potential circulation and transmission of viruses. Avoidance of false positives and sampling bias should also be a focus in future work.

Screening and identification of the AFLP markers linked to a new powdery mildew resistance gene in wheat cultivar Brock.

Wheat cultivar Jing 411 which is susceptible to powdery mildew, wheat cultivar Brock and near isogenic lines (NILs) of Jing411, which are resistant to powdery mildew were analysized for polymorphisms using 225 pairs of AFLP primers Only two pairs of primers Pst+GAC/Mse+ TCT (P1) and Pst+AGC/Mse+ACC (P2) stably produced polymorphic bands between the resistant and susceptible plants. Two specific fragments were obtained. By cloning and sequencing these two specific fragments, it was showed that the specific fragment amplified by primer P1 had 268bp, and the fragment amplified by P2 had 227bp. They were named AFLP marker P1(268) and P2(227) respectively. Linkage analysis of these two markers revealed that the polymorphism existed in a 106 F2 segregating population. These two markers closely linked to a powdery mildew resistance gene in wheat cultivar Brock, linkage distance were 3.6 and 1.9 cM respectively. These two markers will be useful for marker-assisted selection and gene pyramiding in wheat resistance breeding.

[The effect of Haynaldia villosa v chromosome on the mitochondrial proteome of wheat-H. villosa chromosome substitution line and translocation line].

Wheat-Haynaldia villosa chromosome substitution line (6A/6V) and translocation lines (6DL/6VS, 6AL/6VS) were obtained through hybridization of H. villosa with powdery mildew susceptible cultivated wheat. Substitution line and translocation lines contain V chromosome or the chromosome short arm (VS) of H. villosa. They are resistant to powdery mildew. In this study, mitochondrial proteome changes were analyzed by using substitution line (6A/6V), translocation line (6DL/6VS) as experimental materials in order to studying the effects of V chromosome on the mitochondrial proteome and related to powdery mildew resistance. The results indicated that 16 new mitochondrial protein spots (spot1, 22kDa/PI8.5; spot2, 31 kDa/PI 7.5; spot3, 28 kDa/PI 7.0; spot4, 31 kDa/PI 6.5; spot5, 40 kDa/PI 7.5; spot6, 40 kDa/PI 7.4; spot7, 80 kDa/PI 8.4; spot8, 50 kDa/PI 7.5; spot9, 60 kDa/PI 7.3; spot10, 65 kDa/PI 6.6; spot11, 65 kDa/PI 6.6; spot12, 73 kDa/PI 7.5; spot13, 73 kDa/PI 7.7; spot14, 46 kDa/PI 7.4; spot15, 46 kDa/PI 7.3; spot16, 38 kDa/PI 6.3) were produced and 7 mitochondrial protein spots (spot1, 40 kDa/PI 7.5; spot2, 43 kDa/PI 7.6; spot3, 48 kDa/PI 7.5; spot4, 42 kDa/PI 8.0; spot5, 43 kDa/PI 7.5; spot6, 32 kDa/PI 4.8; spot7, 40 kDa/PI 5.5) were absent in substitution line, 7 new mitochondrial protein spots (spotl, 43 kDa/PI 6.3; spot2, 60 kDa/PI 6.5; spot3, 60 kDa/PI 6.4; spot4, 65 kDa/PI 7.5; spot5, 55 kDa/PI 8.2; spot6, 31 kDa/PI 8.0; spot7, 43 kDa/PI 8.0) were produced and 6 mitochondrial protein spots (spot1', 66 kDa/PI 8.3; spot2', 58 kDa/PI 8.5; spot3', 36 kDa/PI 7.0; spot4', 48 kDa/PI 7.7; spot5', 48 kDa/PI 6.8; spot6', 43 kDa/PI 6.2) were absent in translocation line. These experimental results suggest that V chromosome or VS of H. villosa can obviously lead mitochondrial proteome changed. These changes may be associated with resistant to powdery mildew of substitution line and translocation line.