Monoclonal antibodies directed against the sexual binding site of Chlamydomonas eugametos gametes.

Monoclonal antibodies were raised against the mt- sexual agglutinin of Chlamydomonas eugametos gametes. Those that blocked the agglutination site were selected. They were divided into two classes dependent upon whether they gave a weak (class A) or clear positive (class B) reaction with mt- flagellar membranes in an ELISA and an indirect immunofluorescence test using glutaraldehyde-fixed mt- gametes. Class A antibodies were shown to be specific for the agglutinin in an extract of mt- gametes, based on results from immunoblotting, immunoprecipitation, affinity chromatography, and the absence of a reaction with nonagglutinable cells. Surprisingly, class A mAbs also recognized two mt+ glycoproteins, one of which is the mt+ agglutinin. Class B antibodies were shown to bind to several glycoproteins in both mt- and mt+ gametes, including the mt- agglutinin. Fab fragments from class A mAbs blocked the sexual agglutination process, but those from class B did not, even though the parent antibody did. We conclude that the class A epitope lies in or close to the agglutination site of the mt- agglutinin, whereas the class B epitope lies elsewhere on the molecule. We also conclude that the mt- agglutinin is the only component on the mt- flagellar surface directly involved in agglutination. Class A mAbs were found to elicit several reactions displayed by the mt+ agglutinin. They bound to the mt- agglutinin on gamete flagella and induced most of the reactions typical of sexual agglutination, with the exception of flagellar tip activation. None of these reactions was induced by Fab fragments. High concentrations of class A mAbs completely repressed the sexual competence of live mt- gametes, but low concentrations stimulated cell fusion.

Boundaries of telomere conversion in Trypanosoma brucei.

Active genes for variant-specific surface glycoproteins (VSGs) reside in telomeric expression sites and may be replaced by other VSG genes via telomere conversions. The availability of a complete map of expression site 221 in variant 221a made it possible to determine the boundaries of such conversions and the sequences that are involved. We have analysed five trypanosome populations that arose from variant 221a through replacement of the 221 gene by another VSG gene. In each of these relapsed populations the telomere conversion ends at a different position in the expression site. In the relapsed population, 221aR3, the boundary was found in the coding region of an expression-site-associated gene (ESAG). This ESAG-2 codes for a potential 368-aa protein of unknown function; it contains a N-terminal signal peptide for mediating transfer to the endoplasmic reticulum and six potential N-glycosylation sites. It shares these structural features with the ESAG-1 protein encoded in the same expression site. ESAG-2 is a member of a large gene family which includes non-functional genes. In 221aR3, the partial conversion of ESAG-2 by an ESAG-2-like sequence has disrupted the open reading frame. The two ESAG-2 sequences are similar (92% identity) suggesting that sequence homology between telomeres provides the opportunity for gene conversion.

The anatomy and transcription of a telomeric expression site for variant-specific surface antigens in T. brucei.

The variant specific surface glycoprotein (VSG) genes of T. brucei are expressed in telomeric expression sites. We have determined the structure of the active site in trypanosome variant 221a, which contains VSG gene 221, by analysis of cloned DNA segments that represent 65 kb of the 5'-flanking region of the VSG gene. In nuclear run-on experiments, 57 kb of adjacent sequences are cotranscribed with the VSG gene at approximately similar rates and in the alpha-amanitin-resistant manner characteristic of VSG genes. Besides the VSG mRNA, this expression site yields at least seven stable RNAs, suggesting that it is a multicistronic transcription unit. Our results also show that insertion of a transcriptional terminator is not the general mechanism of switching off expression sites.