123 research outputs found

    The gene map of the rabbit III. α and β casein gene synteny

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    The gene map of the rabbit. III. α and β casein gene synteny

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    We are developing the gene map of the rabbit using DNA probes which allow us to investigate non-expressed genes. We have characterized an α and β casein gene synteny have found that neither the α and β casein genes nor the whey acidic protein gene have a syntenic relationship with the other chromosome markers already investigated in our laboratory. Moreover, with the β casein probe we have detected a simple allelic Eco RI restriction-site polymorphism.Nous développons la carte génique du lapin en utilisant des sondes d’ADN cloné qui, par hybridation moléculaire, permettent de caractériser les gènes indépendamment de leur expression. Dans le cadre de cette étude, nous avons mis en évidence une synténie entre les gènes de la caséine α et de la caséine β. Aucune relation de synténie n’a été observée entre les gènes des caséines α et β, ou le gène de la protéine acide du lactosérum et les autres marqueurs chromosomiques déjà étudiés au laboratoire. Les résultats obtenus avec la sonde caséine β montrent un polymorphisme au locus de ce gène sous la dépendance d’un couple d’allèles

    Early Events Associated with Infection of Epstein-Barr Virus Infection of Primary B-Cells

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    Epstein Barr virus (EBV) is closely associated with the development of a vast number of human cancers. To develop a system for monitoring early cellular and viral events associated with EBV infection a self-recombining BAC containing 172-kb of the Epstein Barr virus genome BAC-EBV designated as MD1 BAC (Chen et al., 2005, J.Virology) was used to introduce an expression cassette of green fluorescent protein (GFP) by homologous recombination, and the resultant BAC clone, BAC-GFP-EBV was transfected into the HEK 293T epithelial cell line. The resulting recombinant GFP EBV was induced to produce progeny virus by chemical inducer from the stable HEK 293T BAC GFP EBV cell line and the virus was used to immortalize human primary B-cell as monitored by green fluorescence and outgrowth of the primary B cells. The infection, B-cell activation and cell proliferation due to GFP EBV was monitored by the expression of the B-cell surface antigens CD5, CD10, CD19, CD23, CD39, CD40 , CD44 and the intercellular proliferation marker Ki-67 using Flow cytometry. The results show a dramatic increase in Ki-67 which continues to increase by 6–7 days post-infection. Likewise, CD40 signals showed a gradual increase, whereas CD23 signals were increased by 6–12 hours, maximally by 3 days and then decreased. Monitoring the viral gene expression pattern showed an early burst of lytic gene expression. This up-regulation of lytic gene expression prior to latent genes during early infection strongly suggests that EBV infects primary B-cell with an initial burst of lytic gene expression and the resulting progeny virus is competent for infecting new primary B-cells. This process may be critical for establishment of latency prior to cellular transformation. The newly infected primary B-cells can be further analyzed for investigating B cell activation due to EBV infection

    Pathogenesis, diagnosis and management of pneumorrhachis

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    Pneumorrhachis (PR), the presence of intraspinal air, is an exceptional but eminent radiographic finding, accompanied by different aetiologies and possible pathways of air entry into the spinal canal. By reviewing the literature and analysing a personal case of traumatic cervical PR after head injury, we present current data regarding the pathoanatomy, clinical and radiological presentation, diagnosis and differential diagnosis and treatment modalities of patients with PR and associated pathologies to highlight this uncommon phenomenon and outline aetiology-based guidelines for the practical management of PR. Air within the spinal canal can be divided into primary and secondary PR, descriptively classified into extra- or intradural PR and aetiologically subsumed into iatrogenic, traumatic and nontraumatic PR. Intraspinal air is usually found isolated not only in the cervical, thoracic and, less frequently, the lumbosacral regions but can also be located in the entire spinal canal. PR is almost exceptional associated with further air distributions in the body. The pathogenesis and aetiologies of PR are multifold and can be a diagnostic challenge. The diagnostic procedure should include spinal CT, the imaging tool of choice. PR has to be differentiated from free intraspinal gas collections and the coexistence of air and gas within the spinal canal has to be considered differential diagnostically. PR usually represents an asymptomatic epiphenomenon but can also be symptomatic by itself as well as by its underlying pathology. The latter, although often severe, might be concealed and has to be examined carefully to enable adequate patient treatment. The management of PR has to be individualized and frequently requires a multidisciplinary regime
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