Duplicative activation mechanisms of two trypanosome telomeric VSG genes with structurally simple 5'' flanks.

In the mammalian bloodstream, African trypanosomes express variant surface glycoprotein (VSG) genes from a family of long and complex telomeric expression sites. VSG switching generally occurs by the duplication of different VSG genes into these sites by gene conversion involving a series of 70 base pair (70bp) repeats in the 5' flank. In contrast, when VSG is first synthesised by trypanosomes in the tsetse fly at the metacyclic stage, a separate set of telomeric expression sites is activated. These latter telomeres appear not to act as recipients in gene conversion. We have found that the structure of two such expression sites is simple, with very short 70bp repeat regions and very little other sequence in common with bloodstream expression sites. However, the two telomeres readily act as donors in VSG gene conversion in the bloodstream and we show for one a consistent association of the conversion 5' end point with the short 70bp repeat region. These findings help explain why a very predictable set of VSGs is expressed in the tsetse fly and have implications for VSG gene conversion mechanisms.     

Trypanosome variant surface glycoprotein genes expressed early in infection

We have studied further the genes for trypanosomal variant surface glycoproteins expressed during a chronic infection of rabbits with Trypanosoma brucei, strain 427. We show that there are three closely related chromosomal-internal isogenes for VSG 121; expression of one of these genes is accompanied by the duplicate transposition of the gene to a telomeric expression site, also used by other chromosome-internal VSG genes. The 3' end of the 121 gene is replaced during transposition with another sequence, also found in the VSG mRNAs of two other variants. We infer that an incoming VSG gene duplicate recombines with the resident gene in the expression site and may exchange ends in this process. The extra expression-linked copy of the 121 gene is lost when another gene enters the expression site. However, when the telomeric VSG gene 221 is activated without duplication the extra 121 gene copy is inactivated without detectable alterations in or around the gene. We have also analysed the VSG genes expressed very early when trypanosomes are introduced into rats or tissue culture. The five genes identified in 24 independent switching events were all found to be telomeric genes and we calculate that the telomeric 1.8 gene has a 50% chance of being activated in this trypanosome strain when the trypanosome switches the VSG that is synthesized. We argue that the preferential expression of telomeric VSG genes is due to two factors: first, some telomeric genes reside in an inactive expression site, that can be reactivated; second, telomeric genes can enter an active expression site by a duplicative telomere conversion and this process occurs more frequently than the duplicative transposition of chromosome-internal genes to an expression site.     

Molecular characterization of major histocompatibility complex (B) haplotypes in broiler chickens

In Leghorn (laying) chickens, susceptibility to a number of infectious diseases is strongly associated with the major histocompatibility ( B ) complex. Nucleotide sequence data have been published for six class I ( B-F ) alleles and for class II ( B-Lβ ) alleles or isotypes from 17 Leghorn haplotypes. It is not known if classical B-L or B-F alleles in broilers are identical, at the sequence level, to any Leghorn alleles. This report describes molecular and immunogenetic characterization of two haplotypes from commercial broiler breeder chickens that were originally identified by serology as a single haplotype, but were differentiated serologically in the present work. The two haplotypes, designated B ^A4 and B ^A4variant, shared identical B-G restriction fragment length polymorphism patterns, but differed in one B-Lβ fragment that cosegregated with the serological B haplotype. Furthermore, the nucleotide sequences of the highly variable exons of an expressed B-LβII family gene and B-F gene from the two haplotypes were markedly different from each other. Both the B-LβII family and B-F gene sequences from the B ^A4 haplotype were identical to the sequences obtained from the reference B ²¹ haplotype in Leghorns; however, in the B ^A4 haplotype the B-Lβ ²¹ and B-F ²¹ alleles were in linkage with B-G alleles that were not G ²¹. The nucleotide sequences from B ^A4variant were unique among the reported chicken B-LβII family and B-F alleles.     

Trypanosoma brucei: frequent loss of a telomeric variant surface glycoprotein gene

We have observed the loss of an inactive telomeric variant surface glycoprotein (VSG) gene that is located on a minichromosome in Trypanosoma brucei. If this is due to gene conversion, it is the third "silent" gene conversion (i.e., one that does not produce an antigenic switch) detected in 19 antigenic switches of the IsTaR 1 serodeme. This is surprisingly frequent since the immune response cannot select against the inactive gene. We estimate that 10(-1) to 10(-3) telomeric VSG gene conversions occur per generation, which is at least 100 times more frequent than antigenic switching. Since all three "silent" gene conversions involved an IsTat 5 VSG gene, the frequency may vary among telomeric VSG genes. However, the high gene conversion frequency for the 5 VSG gene does not ensure a higher antigenic switch frequency than other telomeric VSG genes for which we have probes. These results suggest that gene conversion rapidly alters the repertoire of telomeric VSG genes, possibly including those on minichromosomes, producing a continual variation in the VSG genes that are more likely to be expressed.     

Gene conversions mediating antigenic variation in Trypanosoma brucei can occur in variant surface glycoprotein expression sites lacking 70-base-pair repeat sequences.

African trypanosomes undergo antigenic variation of their variant surface glycoprotein (VSG) coat to avoid immune system-mediated killing by their mammalian host. An important mechanism for switching the expressed VSG gene is the duplicative transposition of a silent VSG gene into one of the telomeric VSG expression sites of the trypanosome, resulting in the replacement of the previously expressed VSG gene. This process appears to be a gene conversion reaction, and it has been postulated that sequences within the expression site may act to initiate and direct the reaction. All bloodstream form expression sites contain huge arrays (many kilobase pairs) of 70-bp repeat sequences that act as the 5' boundary of gene conversion reactions involving most silent VSG genes. For this reason, the 70-bp repeats seemed a likely candidate to be involved in the initiation of switching. Here, we show that deletion of the 70-bp repeats from the active expression site does not affect duplicative transposition of VSG genes from silent expression sites. We conclude that the 70-bp repeats do not appear to function as indispensable initiation sites for duplicative transposition and are unlikely to be the recognition sequence for a sequence-specific enzyme which initiates recombination-based VSG switching.     

The IsTat 1.3 VSG multigene family in Trypanosoma brucei: retention of the expression linked copy through multiple antigenic switches.

In the IsTaR 1 serodeme of T. brucei the 3 variant surface glycoprotein (VSG) gene family contains about 10 members, one of which has a telomeric location on a minichromosome. The expression linked copy (ELC) of the 3 VSG gene which occurs in an antigenic variant expressing the 3 VSG, also has a telomeric location but unlike the minichromosomal 3 VSG gene has restriction sites upstream from the 5' barren region. This ELC is retained on the same telomere in a subsequent variant that expresses a telomeric 7 VSG ELC and in relapse variants and procyclic forms derived from variant antigenic types (VATs) 3 and 7. The 7 ELC has a restriction map upstream from the 5' barren region that differs from, but is similar to, that of the 3 ELC. These data indicate that the 3 and 7 ELCs are on different telomeres when expressed.     

Coordinate transcription of variant surface glycoprotein genes and an expression site associated gene family in Trypanosoma brucei

Trypanosoma brucei variant surface glycoprotein (VSG) genes are activated either by duplicative (DA) transposition of the gene to a pre-activated expression site or by nonduplicative (NDA) activation of a previously silent telomeric gene. We have obtained a recombinant clone spanning the 5' barren region of the expression linked copy of the duplicated VSG gene 117a. By DNA sequence and hybridization analyses we have identified a pleomorphic family of 14-25 non-VSG genes that lie upstream of both DA and NDA VSG expression sites. These expression site associated genes (ESAGs) encode 1.2 kb poly(A)+ mRNAs that are specifically transcribed from the active VSG expression telomere in mammalian bloodstream stages of T. brucei but, in common with VSG genes, are not transcribed in procyclic culture forms. cDNA and genomic sequences predict open reading frames that are conserved in the two ESAGs examined.     

Engineering of the yeast ubiquitin ligase Rsp5: isolation of a new variant that induces constitutive inactivation of the general amino acid permease Gap1

Rsp5 is an essential ubiquitin-protein ligase in Saccharomyces cerevisiae . We found previously that the Ala401Glu rsp 5 mutant is hypersensitive to various stresses that induce protein misfolding, suggesting that Rsp5 is a key enzyme for yeast cell growth under stress conditions. To isolate new Rsp5 variants as suppressors of the A401E mutant, PCR random mutagenesis was used in the rsp5 ^A401E gene, and the mutagenized plasmid library was introduced into rsp5 ^A401E cells. As a phenotypic suppressor of rsp5 ^A401E cells, we isolated a quadruple variant (Thr357Ala/Glu401Gly/Lys764Glu/Glu767Gly) on a minimal medium containing the toxic proline analogue azetidine-2-carboxylate (AZC). Site-directed mutagenesis experiments showed that the rsp5 ^T357A/K764E cells were much more tolerant to AZC than the wild-type cells, due to the smaller amounts of intracellular AZC. However, the T357A/K764E variant Rsp5 did not reverse the hypersensitivity of rsp5 ^A401E cells to other stresses such as high growth temperature, ethanol, and freezing treatment. Interestingly, immunoblot and localization analyses indicated that the general amino acid permease Gap1, which is involved in AZC uptake, was absent on the plasma membrane and degraded in the vacuole of rsp5 ^T357A/K764E cells before the addition of ammonium ions. These results suggest that the T357A/K764E variant Rsp5 induces constitutive inactivation of Gap1.     

Nucleotide sequence of a Trichophyton mentagrophytes HindIII mitochondrial DNA fragment containing at RNA gene cluster

Abstract A 0.85-kb Hin dIII mitochondrial DNA fragment of the dermatophytic fungus Trichophyton mentagrophytes has been sequenced. The fragment contains eight complete genes which corresponds to a tRNA gene cluster. From 5' to 3', the sequenced genes code for tRNA^thr, tRNA^glu, tRNA^val, tRNA^met1, tRNA^met3, tRNA^leu, tRNA^ala, and tRNA^phe. This tRNA gene cluster is located downstream of the larger ribosomal RNA gene. The particularities ofthe sequenced genes and their comparison with other fungal tRNA mitochondrial genes are reported.     

Telomere conversion in trypanosomes.

Activation of the gene coding for variant surface glycoprotein (VSG) 118 in Trypanosoma brucei proceeds via a duplicative transposition to a telomeric expression site. The resulting active expression-linked extra copy (ELC) is usually flanked by DNA that lacks sites for most restriction enzymes and that is thought to interfere with the cloning of the ELC as recombinant DNA in Escherichia coli. We have circumvented this problem by cloning an aberrant 118 ELC gene, flanked at the 3'-side by at least 1 kb DNA, that contains restriction enzyme sites. Our analysis shows that this DNA and the 3'-end of the 118 ELC gene are derived from another VSG gene (1.1006) that is permanently located at a telomeric position. We propose that the 3'-end of the 1.1006 gene and (all of) its 3' flanking sequence moved to the expression site by a telomere conversion. Such a telomere conversion can also account for the appearance of an extra copy of the 1.1006 gene detected in a sub-population of our trypanosome strain.     

Degradation, Recycling, and Shedding of Trypanosoma brucei Variant Surface Glycoprotein

ABSTRACT. Trypanosoma brucei bloodstream forms express a densely packed surface coat consisting of identical variant surface glycoprotein (VSG) molecules. This surface coat is subject to antigenic variation by sequential expression of different VSG genes and thus enables the cells to escape the mammalian host's specific immune response. VSG turnover was investigated and compared with the antigen switching rate. Living cells were radiochemically labeled with either ¹²⁵I-Bolton-Hunter reagent or ³⁵S-methionine, and immunogold-surface labeled for electron microscopy studies. The fate of labeled VSG was studied during subsequent incubation or cultivation of labeled trypanosomes. Our data show that living cells slowly released VSG into the medium with a shedding rate of 2.2 ± 0.6% h⁻¹ (t_1/2= 33 ± 9 h). In contrast, VSG degradation accounted for only 0.3 ± 0.06% h⁻¹ (t_1/2= 237 ± 45 h) and followed the classical lysosomal pathway as judged by electron microscopy. Since VSG uptake by endocytosis was rather high, our data suggest that most of the endocytosed VSG was recycled to the surface membrane. These results indicate that shedding of VSG at a regular turnover rate is sufficient to remove the old VSG coat within one week, and no increase of the VSG turnover rate seems to be necessary during antigenic variation.     

The use of incomplete genes for the construction of a Trypanosoma equiperdum variant surface glycoprotein gene.

The expression of Trypanosoma equiperdum variant surface protein (VSG) 78 is accomplished by the duplicative transposition of silent basic copy (BC) genes into a telomer-linked expression site to form an expression-linked copy (ELC). In two independent isolates expressing VSG 78, the ELC is a composite gene. The analysis of VSG 78 cDNA clones from these two Bo Tat 78 isolates and the respective BC genes revealed that both ELCs were constructed from the same three BC genes, a 3' BC which donated the last 255 bp of each ELC and two closely related 5' BCs. Although sequences of both 5' BC genes were found in each ELC, the junction with the 3' BC was provided by the same 5' BC in both cases. This 5' BC is an incomplete gene with insufficient open reading frame to code for a complete VSG and thus can only be used when joined to a competent 3' end. Furthermore, both 5' BC genes lack a conserved 14 nucleotide sequence found on all VSG mRNAs. These results support a model in which composite gene formation plays a role in the determination of the order of VSG expression. They also illustrate similarities between immunoglobulin gene and VSG gene construction.     

Potassium channels in barley: cloning, functional characterization and expression analyses in relation to leaf growth and development

It is not known how the uptake and retention of the key osmolyte K⁺ in cells are mediated in growing leaf tissue. In the present study on the growing leaf 3 of barley, we have cloned the full-length coding sequence of three genes which encode putative K⁺ channels ( HvAKT1 , HvAKT2 , HvKCO1 / HvTPK1 ), and of one gene which encodes a putative K⁺ transporter ( HvHAK4 ). The functionality of the gene products of HvAKT1 and HvAKT2 was tested through expression in Xenopus laevis oocytes. Both are inward-rectifying K⁺ channels which are inhibited by Cs⁺. Function of HvAKT1 in oocytes requires co-expression of a calcineurin-interacting protein kinase ( At CIPK23) and a calcineurin B-like protein (AtCBL9) from Arabidopsis , showing cross-species complementation of function. In planta , HvAKT1 is expressed primarily in roots, but is also expressed in leaf tissue. HvAKT2 is expressed particularly in leaf tissue, and HvHAK4 is expressed particularly in growing leaf tissue. Within leaves, HvAKT1 and HvAKT2 are expressed predominantly in mesophyll. Expression of genes changes little in response to low external K⁺ or salinity, despite major changes in K⁺ concentrations and osmolality of cells. Possible contributions of HvAKT1 , HvAKT2 , HvKCO1 and HvHAK4 to regulation of K⁺ relations of growing barley leaf cells are discussed.