Fertilization and zygote development are obligate features of the malaria parasite life cycle and occur during parasite transmission to mosquitoes. The surface protein PFS48/45 is expressed by male and female gametes of Plasmodium falciparum and PFS48/45 antibodies prevent zygote development and transmission. Here, gene disruption was used to show that Pfs48/45 and the ortholog Pbs48/45 from a rodent malaria parasite P. berghei play a conserved and important role in fertilization. p48/45- parasites had a reduced capacity to produce oocysts in mosquitoes due to greatly reduced zygote formation. Unexpectedly, only male gamete fertility of p48/45- parasites was affected, failing to penetrate otherwise fertile female gametes. P48/45 is shown to be a surface protein of malaria parasites with a demonstrable role in fertilization.
Abstract. The sequence of tubulin-tyrosine ligase (TTL), the enzyme catalyzing the ATP-dependent posttranslational addition of a tyrosine to the carboxyterminal end of detyrosinated ot-tubulin, has been determined. TTL from bovine and porcine brain was purified by immunoaffinity chromatography and extensively characterized by protein sequencing. Oligonucleotides derived from the protein sequence were synthesized and partial eDNA sequences were obtained using reversed transcribed brain mRNA in polymerase chain reactions. Polymerase chain reaction fragments were used to isolate a full-length eDNA clone from a randomly primed hgtl0 eDNA library obtained from embryonic porcine brain mRNA. Porcine TTL is encoded by 1,137 nucleotides corresponding to 379 amino acid residues. It has a molecular weight of 43,425 and a calculated isoelectric point of 6.51. Northern blot analysis revealed a surprisingly long mRNA (~ 6 kb in embryonic porcine brain). The protein sequence of TTL shares no extended homology with the sequences in the data banks. TTL contains a potential serine phosphorylation site for cAMP-dependent protein kinase (RKAS at positions 73 to 76). Residues 244 to 258 lie at the surface of the molecule. A rabbit antibody raised against a synthetic peptide corresponding to this sequence binds to native TTL. The same sequence contains the cleavage site for endoproteinase Glu-C (residue 248) previously shown to convert TTL into a nicked derivative in which the two fragments still form a tight complex but don't display enzymatic activity.
Cytoplasmic intermediate filament (IF) proteins of Caenorhabditis elegans are encoded by a dispersed multigene family comprising at least eight genes which map to three linkage groups. Exon sequences and intron patterns define three distinct subfamilies. While all eight IF genes display the long coil 1b subdomain of nuclear lamins, only six genes (a1‐a4, b1 and b2) retain a lamin‐like tail domain. Two genes (c1 and c2) have acquired entirely novel tail domains. The overall sequence identity of the rod domains is only 29%. The gene structures show a strong drift in number and positions of introns, none of which are common to all genes. Individual genes share only one to four intron locations with the Helix aspersa IF gene, but all eight nematode genes together account for nine of the 10 introns of the gastropod gene. All C.elegans IF genes are transcribed and all except gene c2 produce trans‐spliced mRNAs. Alternatively spliced mRNAs arise from genes a1, b2 and c2 through several mechanisms acting at the transcriptional and posttranscriptional levels. These involve the alternative use of distinct promoters, polyadenylation sequences and both cis and trans RNA splice sites. The resulting sequence variations are restricted to the non‐helical end domains. Minimally 12 distinct IF proteins are encoded by the various mRNAs. Different abundances in mixed‐stage nematode populations suggest cell type‐ and/or stage‐specific expression of individual mRNAs.
The structure of the single gene encoding the cytoplasmic intermediate filament (IF) proteins in non‐neuronal cells of the gastropod Helix aspersa is described. Genomic and cDNA sequences show that the gene is composed of 10 introns and 11 exons, spanning greater than 60 kb of DNA. Alternative RNA processing accounts for two mRNA families which encode two IF proteins differing only in their C‐terminal sequence. The intron/exon organization of the Helix rod domain is identical to that of the vertebrate type III IF genes in spite of low overall protein sequence homology and the presence of an additional 42 residues in coil 1b of the invertebrate sequence. Intron position homology extends to the entire coding sequence comprising both the rod and tail domains when the invertebrate IF gene is compared with the nuclear lamin LIII gene of Xenopus laevis presented in the accompanying report of Döring and Stick. In contrast the intron patterns of the tail domains of the invertebrate IF and the lamin genes differ from those of the vertebrate type III genes. The combined data are in line with an evolutionary descent of cytoplasmic IF proteins from a nuclear lamin‐like progenitor and suggest a mechanism for this derivation. The unique position of intron 7 in the Helix IF gene indicates that the archetype IF gene arose by the elimination of the nuclear localization sequence due to the recruitment of a novel splice site. The presumptive structural organization of the archetype IF gene allows predictions with respect to the later diversification of metazoan IF genes. Whereas models proposing a direct derivation of neurofilament genes seem unlikely, the earlier speculation of an mRNA transposition mechanism is compatible with current results.
Intermediate filaments (IF) isolated from the oesophagus epithelium of the snail Helix pomatia contain two polypeptides of mol. wt 66,000 (A) and 52,000 (B), which we have now characterized by in vitro self‐assembly studies and by protein sequences. A and B can each form morphologically normal IF and share extended regions of sequence identity. All A‐specific sequences seem to locate to an extension of the carboxyl‐terminal domain. Although the Helix protein(s) reveal the IF‐consensus sequences at the ends of the coiled‐coil, the remainder of the rod domain shows conservation of sequence principles rather than extended homology, when compared with any subtype of vertebrate IF proteins. Interestingly, the Helix proteins have the longer coil 1b domain found in nuclear lamins and not in cytoplasmic IF proteins of vertebrates. They lack, however, the karyophilic signal sequence typical for lamins. Obvious implications for IF evolution and structure are discussed.
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