BACKGROUNDCystic echinococcosis due to Echinococcus granulosus (E. granulosus) is one of the most important chronic helminthic diseases, especially in sheep/cattle-raising regions. The larval stage of the parasite forms a cyst that grows in the liver, lung, or other organs of the host. To ensure a long life in the host tissues, the parasite establishes complex inter-cellular communication systems between its host to allow its differentiation toward each larval stage. Recent studies have reported that this communication is associated with the extracellular signal-regulated kinase (ERK) mitogen-activated protein kinase cascade in helminth parasites, and in particular that these protein kinases might serve as effective targets for a novel chemotherapy for cystic echinococcosis. The aim of the present study investigated the biological function of a novel ERK ortholog from E. granulosus, EgERK.

METHODSDNA encoding EgERK was isolated from protoscolices of E. granulosus and analyzed using the LA Taq polymerase chain reaction (PCR) approach and bioinformatics. Reverse transcription PCR (RT-PCR) was used to determine the transcription level of the gene at two different larval tissues. Western blotting was used to detect levels of EgERK protein. The expression profile of EgERK in protoscolices was examined by immunofluorescence.

RESULTSWe cloned the entire Egerk genomic locus from E. granulosus. In addition, two alternatively spliced transcripts of Egerk, Egerk-A, and Egerk-B were identified. Egerk-A was found to constitutively expressed at the transcriptional and protein levels in two different larval tissues (cyst membranes and protoscolices). Egerk-A was expressed in the tegumental structures, hooklets, and suckers and in the tissue surrounding the rostellum of E. granulosus protoscolices.

CONCLUSIONSWe have cloned the genomic DNA of a novel ERK ortholog from E. granulosus, EgERK (GenBank ID HQ585923), and found that it is constitutively expressed in cyst membrane and protoscolex. These findings will be useful in further study of the biological functions of the gene in the growth and development of Echinococcus and will contribute to research on novel anti-echinococcosis drug targets.

Animals ; Blotting, Western ; Computational Biology ; DNA, Helminth ; genetics ; Echinococcus granulosus ; enzymology ; genetics ; Genome, Helminth ; genetics ; Helminth Proteins ; genetics ; metabolism ; Polymerase Chain Reaction

[Abstract] ObjectVisualizing the superficial cerebellar vein and its tributaries on suscepxibility weighted imaging (SWI), and to construct superficial cerebellar vein network. Methods According to the inclusion criteria, 80 healthy volunteers (40 males and 40 females) were selected for 3. 0 T MRI scans to obtain conventional sequence cross-section, sagittal tomographic images, and SWI image data. Post-processing was performed on the Extended MR workspace 2. 6. 3. 4 image workstation to reconstruct minimum intensity projection(mIP) images. SPSS 21. 0 statistical software was used to analyze and process each data, and the diameter measurement result were expressed as mean ± standard deviation. Results Both SWI and mIP could image the structures of the cerebellum and its veins. The cerebellar veins were divided into deep and superficial parts. The superficial cerebellar veins were divided into two groups: the vermis and the cerebellar hemispheres. The superficial vein of the cerebellar vermis consisted of superior vermis vein [diameter: (1. 21±0. 24)mm, occurrence rate: 92. 16%], summit vein [ diameter: (0. 66 ± 0. 05) mm, occurrence rate: 95%], mountain vein [diameter: (0. 76±0. 03)mm, occurrence rate: 100%], inferior vermis vein [diameter: (1. 40±0. 27)mm, occurrence rate: 99. 02%]. The superficial cerebellar hemisphere vein consists of anterior superior cerebellar vein [diameter: (1. 09± 0. 12)mm, occurrence rate: 100%], posterior superior cerebellar vein [diameter: (0. 88±0. 13) mm, occurrence rate: 70%], anterior inferior cerebellar vein [ diameter: (1. 34 ± 0. 15) mm, occurrence rate: 100%], posterior inferior cerebellar vein [ diameter: (1. 11 ± 0. 09) mm, occurrence rate: 92. 5%]. The deep veins were divided into cerebellomesencephalic fissure group, cerebellopontine fissure group, and cerebellomedullary fissure group. Conclusion SWI can display the microstructure and venules of the cerebellum, and can construct a network of superficial cerebellar veins.

Objective Make use of image dentate nucleus and the veins around it on susceptibility weighted images (SWI), explore the correlation between the location of hilum of dentate nucleus and the venous variation of dentate nucleus. Methods Selecting 51 healthy adults (24 men, 27 women) at the age between 18 and 30 years old to get the original images on 3. 0T MR. Process the original images by minimum intensity projections (mIP) observed and analyzed the morphology of dentate nucleus and veins around it on original and processed images. Results The length of dentate nucleus was (16. 64±0. 20)mm, and the width was (8. 36±0. 14)mm. There was no significant difference between bilateral dentate nucleus. The median angle of the long axis of the dentate nucleus was 26. 80° (interquartile distance was 34. 58°). The venous network of dentate nucleus was formed in 2 groups of veins: the lateral group, drained by the vein of the horizontal fissure and nuclear vein; the medial group, drained by vermian vein and central vein of dentate nucleus. These two groups had been further typing as follows: the lateral anterior group drained by the nuclear vein, finally opening to superior petrosal sinus; the lateral median group had plenty of small veins of lateral dentate nucleus converge into the vein of the horizontal fissure; the lateral posterior group drained by a lot of very small veins converging to vermian veins or medullary veins; the medial anterior group that the central vein of dentate nucleus and the paravermian vein were jointed at hilum of dentate nucleus, opening into straight sinus; the medial posterior group usually converged into tributaries of vermian vein, or converged with paravermian vein into tributaries of vermian vein. Totally 75. 49% of hilums of dentate nucleus were located at upper inner quadrant, the other 24. 51% of them were located at lower inner quadrant. Conclusion Dentate nucleus and its veins are clearly visible on the susceptibility weighted images, and the location of the hilum of dentate nucleus may be related to the abouchement of paravermian vein.