Expression, cellular distribution and protein binding of the glioma amplified sequence (GAS41), a highly conserved putative transcription factor.

The glioma amplified sequence 41 (GAS41) was previously isolated by microdissection mediated cDNA capture from the glioblastoma multiforme cell line TX3868 and shown to be frequently amplified in human gliomas. We determined the complete cDNA sequence of the GAS41 gene, demonstrated that the GAS41 protein is evolutionarily conserved, specifically at the N-terminus, and identified the yeast transcription factor tf2f domain within the GAS41 sequence. A human multiple-tissue Northern blot revealed ubiquitous expression of GAS41 with the highest expression in human brain. After generating polyclonal antibodies we found GAS41 protein expression in the nucleus of the TX3868 cell line by Western blot analysis and immunofluorescence microscopy. The nuclear localization was confirmed for several human tumors including gliomas of different grades of malignancy. In neuroblastoma however, GAS41 was found in the nucleoli but not in the nucleoplasm. Yeast two-hybrid screening of the TX3868 cell line identified the nuclear mitotic apparatus protein (NuMA), the KIAA1009 protein, and prefoldin subunit 1 (PFDN1) as potential interacting partners of GAS41. We generated a polyclonal antibody against the KIAA1009 protein and we demonstrated that the KIAA1009 protein is a nuclear protein, which appears to be co-localized with the GAS41 protein and NuMA.

Identification of a nuclear variant of MGEA5, a cytoplasmic hyaluronidase and a beta-N-acetylglucosaminidase.

MGEA5 was originally identified to be a novel human hyaluronidase, which is immunogenic in meningioma patients. Recently an N-acetylglucosaminidase was reported with identical sequence. Here, we define the origin of a splice variant by determining the genomic organization of the mgea5 gene. We find the splice variant missing a putative acetyltransferase domain of MGEA5. As for evolutionary analysis, we show that the MGEA5 is highly conserved in higher eukaryotes. As for expression analysis, we find both mRNA variants ubiquitously expressed in various human tissues and throughout mouse development. We generated polyclonal antibodies against MGEA5s/5 and identified proteins of 75 and 130 kDa, indicating posttranslational modifications of the larger protein. Cell fractionation revealed the cytoplasmic/cytoskeletal localization of the 130-kDa protein and the nuclear localization of the 75-kDa protein. We propose a model in which MGEA5 functions both as a hyaluronidase and an N-acetylglucosaminidase.

Probing the human natural autoantibody repertoire using an immunoscreening approach.

While an increasing number of studies report the presence of antibodies capable of recognizing self-antigens, the function of these natural autoantibodies remains elusive. A variety of concepts has been advanced ranging from evolutionarily tolerated but non-functional natural autoantibodies to autoantibodies effecting various biological functions. Known IgM, IgG, and IgA natural autoantibodies are directed against various antigens, including nuclear and cell surface proteins. To explore further autoantibodies and their autoantigens, we employed an immunological screening method called SEREX recently used to characterize tumour-expressed antigens eliciting an immune response in patients [1]. Sera from 12 individuals were used to screen a cDNA expression library prepared from a cytogenetically normal meningioma to identify antigens reactive with normal human sera from individuals without obvious disease. Nineteen reactive normal antigen clones were identified representing 15 different antigens, including nine genes with known functions, five genes with unknown functions, and one gene with a novel sequence not present in the databases. Of the 12 individual normal sera tested, 75% were reactive to one or more of the 15 different antigens with two highly reactive sera demonstrating reactivity with 33% of the antigens. When screening the same meningioma expression library with serum from the patient, eight antigens were identified that were totally different from those identified using sera from normal individuals. This SEREX immunological screening method presents a new option for probing the natural autoantibody repertoire and identifying normal antigens whose functions may provide additional insights into how natural autoantibodies effect various biological functions.