Midline lineages in grasshopper produce neuronal siblings with asymmetric expression of Engrailed

The median neuroblast lineage of grasshopper has provided a model for the development of differing neuronal types within the insect central nervous system. According to the prevailing model, neurons of different types are produced in sequence. Contrary to this, we show that each ganglion mother cell from the median neuroblast produces two neurons of asymmetric type: one is Engrailed positive (of interneuronal fate); and one is Engrailed negative (of efferent fate). The mature neuronal population, however, results from differential neuronal death. This yields many interneurons and relatively few efferent neurons. Also contrary to previous reports, we find no evidence for glial production by the median neuroblast. We discuss evidence that neuronal lineages typically produce asymmetric progeny, an outcome that has important developmental and evolutionary implications.     

A Wnt-Wnt situation

A recent Juan March Foundation workshop on "wnt genes and Wnt signaling" brought developmental and cancer biologists together to share some of the latest advances in Wnt research. Discussion topics included molecular, genetic, and genomic dissections of wnt genes in embryogenesis and cancer, Wnt signaling components and downstream targets, interactions with other signaling pathways, cell biological aspects of Wnt signaling, and a first glimpse of a purified Wnt protein.     

Chromoblastomycosis in Mainland China: A Systematic Review on Clinical Characteristics

Chromoblastomycosis is one of the most frequent chronic infections caused by melanized fungi. In order to evaluate the clinical characteristics of chromoblastomycosis in Mainland China, we performed an evidence-based review of published literature. PubMed and Chinese-language database of CNKI, VIP and Wanfang data during January 1990–August 2011 were searched. Epidemiology, clinical features, laboratory findings, therapy and prognosis were analyzed. Cladophialophora carrionii was the most common causative agent in the north of the Mainland China, and Fonsecaea monophora and F. pedrosoi were the most common agents in the southern part of the Mainland China. Infection commonly initiated after the etiologic agents gain entrance through puncture wounds and more common involved extremities of the males. Skin lesions were found in different sites, like the extremities, buttocks, trunk and face, and presented diversity morphology. There were about seven different clinical types found in Mainland China: plaque type, tumoral type, cicatricial type, verrucous type, pseudo-vacuole type, eczymatous type and mixed type of lesions. The success of treatment for chromoblastomycosis was related to the causative agent, the clinical form and severity of the lesions. Most of the patients could be treated successfully with the physical treatment, chemotherapy and/or combination therapy. The itraconazole, terbinafine or a combination of both were commonly medication for these mycosis patients. Physical methods were usually indicated to support chemotherapy with some severe forms and long-lasting cases. Photodynamic therapy has been extended from the oncological field to that of antimicrobial chemotherapy in these years. We applied it on some recalcitrant cases of chromoblastomycosis and found its good clinical response, and hopeful it could be a promising therapy in near future.     

A Novel Little Membrane Protein Confers Salt Tolerance in Rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

Plasma membrane proteins play critical roles in sensing and responding abiotic and biotic stresses in plants. In the present study, we characterized a previously unknown gene stress associated little protein 1 (SALP1) encoding a plasma membrane protein. SALP1, a small and plant-specific membrane protein, contains only 74 amino acid residues. SALP1 was constitutively expressed in various rice tissues while highly expressed in roots, leaf blade, and immature panicles. Expression analysis indicated that SALP1 was induced by various abiotic stresses and abscisic acid (ABA). Subcellular localization assay indicated that SALP1 was localized on plasma membrane in rice protoplast cells. Overexpressing of SALP1 in rice improved salt tolerance through increasing free proline contents and the expression level of OsP5CS gene, and balancing ion contents under salt stress. Moreover, SALP1 transgenic rice showed reduced sensitivity to ABA treatment, and expression level of SALP1 is not altered by ABI5-like 1 protein. Conclusively, SALP1, a novel membrane protein, is involved in salt tolerance through an ABA-independent signaling pathway in rice.