The development of the macrogamete and oocyst wall in Eimeria maxima: immuno-light and electron microscopy.

We have identified, and followed the development of three macrogamete organelles involved in the formation of the oocyst wall of Eimeria maxima. The first were small lucent vacuoles that cross-reacted with antibodies to the apple domains of the Toxoplasma gondii microneme protein 4. They appeared early in development and were secreted during macrogamete maturation to form an outer veil and were termed veil forming bodies. The second were the wall forming bodies type 1, large, electron dense vacuoles that stained positively only with antibodies raised to an enriched preparation of the native forms of 56 (gam56), 82 (gam82) and 230 kDa (gam230) gametocyte antigens (termed anti-APGA). The third were the wall forming bodies type 2, which appeared before the wall forming bodies type 1 but remain enclosed within the rough endoplasmic reticulum and stained positively with antibodies raised to recombinant versions of gam56 (anti-gam56), gam82 (anti-gam82) and gam230 (anti-gam230) plus anti-APGA. At the initiation of oocyst wall formation, the anti-T. gondii microneme protein 4 positive outer veil detached from the surface. The outer layer of the oocyst wall was formed by the release of the contents of wall forming bodies type 1 at the surface to form an electron dense, anti-APGA positive layer. The wall forming bodies type 2 appeared, subsequently, to give rise to the electron lucent inner layer. Thus, oocyst wall formation in E. maxima represents a sequential release of the contents of the veil forming bodies, wall forming bodies types 1 and 2 and this may be controlled at the level of the rough endoplasmic reticulum/Golgi body.

Chromatin remodelling during the life cycle of trypanosomatids.

The mechanisms which control the expression of developmentally regulated genes in trypanosomatids remain unclear. The genes are grouped together into transcription units that are co-transcribed to yield polycistronic RNAs. Trans-splicing and polyadenylation give rise to mature, monocistronic mRNAs. It is difficult to imagine that expression of these genes is controlled at the level of transcription initiation because this would suggest that the genes are transcribed at the same rate. This is not the case, because at any given developmental stage in trypanosomes or Leishmania, genes transcribed from the same transcription unit are expressed at different levels within the cell. Consequently, these parasites must rely on post-transcriptional or post-translational mechanisms to generate the appropriate levels of gene product within the cell. There are no well-established examples of RNA polymerase II promoters in trypanosomes or Leishmania. However, the promoters for genes encoding the variant surface glycoprotein (VSG) and the procyclic acidic repetitive protein (PARP) have been identified and resemble ribosomal RNA polymerase I promoters. In higher eukaryotes where the mechanisms regulating transcription are clearer, there is increasing evidence that epigenetic factors, such as histones and modified bases, influence gene expression. Chemical modification of these factors can restructure chromatin and lead to gene activation or silencing. In trypanosomatids, an epigenetic mechanism for the control of developmentally expressed genes is a possibility. In this review, chromatin remodelling during the life and cell cycle of trypanosomes and Leishmania is explored, and the influence of epigenetic factors such as histones and modified bases on this process is discussed.

Ecto-phosphodiesterase/pyrophosphatase of lymphocytes and non-lymphoid cells: structure and function of the PC-1 family.

Many developmentally regulated membrane proteins of lymphocytes are ecto-enzymes, with their active sites on the external surface of the cell. These enzymes commonly have peptidase, phosphodiesterase or nucleotidase activity. Their biological roles are just beginning to be discovered. Although their expression is usually associated with particular stages of lymphoid differentiation, the same gene products are often expressed on the surface of certain non-lymphoid cell types outside the immune system, indicating that their functions cannot be unique to lymphocytes, nor can they be ubiquitous. The plasma cell membrane protein PC-1 (phosphodiesterase I; EC 3.1.4.1/nucleotide pyrophosphatase; EC 3.6.1.9), which was one of the first serological markers for lymphocyte subsets to be discovered, is a typical example. Within the immune system, PC-1 is confined to plasma cells, which represent about 0.1% of lymphocytes. However, PC-1 is also expressed on cells of the distal convoluted tubule of the kidney, chondrocytes, osteoblasts, epididymis and hepatocytes. Recent work has shown that PC-1 is a member of a multigene family of ecto-phosphodiesterases that currently has two other members, PD-1 alpha (autotaxin) and PD-1 beta (B10). Within this family, the extracellular domains are highly conserved, especially around the active site. In contrast, the transmembrane and cytoplasmic domains are highly divergent. Individual members of the eco-phosphodiesterase family have distinct patterns of distribution in different cell types, and even within the same cell. For example, PC-1 is present only on the basolateral surface of hepatocytes, while B10 (PD-1 beta) is confined to the apical surface. Analysis of conservation and differences in the sequence of their cytoplasmic tails may illuminate intracellular targetting signals. Ecto-phosphodiesterases may play a part in diverse activities in different tissues, including recycling of nucleotides. They may also regulate the concentration of pharmacologically active extracellular compounds such as adenosine or its derivatives and cell motility. Some members may modulate local concentrations of pyrophosphate, and hence influence calcification in bone and cartilage.

Histone H1 expression varies during the Leishmania major life cycle.

The deduced amino acid sequence of Leishmania major sw3 cDNA reveals the presence of characteristic histone H1 amino acid motifs. However, the open reading frame is of an unusually small size for histone H1 (105 amino acids) because it lacks the coding potential for the central hydrophobic globular domain of linker histones present in other eukaryotes. Here, we provide biochemical evidence that the SW3 protein is indeed a L. major nuclear histone H1, and that it is differentially expressed during the life cycle of the parasite. Due to its high lysine content, the SW3 protein can be purified to a high degree from L. major nuclear lysates with 5% perchloric acid, a histone H1 preparative method. Using an anti-SW3 antibody, this protein is detected as a 17 kDa or as a 17/19 kDa doublet in the nuclear subfraction in different L. major strains. The nuclear localization of the SW3 protein is further supported by immunofluorescence studies. During in vitro promastigote growth, both the sw3 cytoplasmic mRNA and its protein progressively accumulate within parasites from early log phase to stationary phase. Within amastigotes, the high level of H1 expression is maintained but decreases when amastigotes differentiate into promastigotes. Together, these observations suggest that the different levels of this histone H1 protein could influence the varying degrees of chromatin condensation during the life-cycle of the parasite, and provide us with tools to study this mechanism.

Autophosphorylation of PC-1 (alkaline phosphodiesterase I/nucleotide pyrophosphatase) and analysis of the active site.

PC-1 is an ecto-enzyme possessing alkaline phosphodiesterase I (EC 3.1.4.1) and nucleotide pyrophosphatase (EC 3.6.1.9) activities. It has also been proposed to be an ecto-protein kinase capable of phosphorylating itself as well as exogenous proteins. We have investigated the phosphorylation capability of PC-1 and have developed a novel method for its detection and characterization based on autophosphorylation, which allows detection without the use of antibodies. When cells expressing membrane PC-1 were held on ice with [gamma-32P]ATP, SDS/PAGE of whole cell lysates showed a single band which was PC-1; this band was absent in cells not expressing PC-1. Immunoprecipitates of soluble PC-1 isolated from culture supernatants of cells expressing PC-1 were also capable of autophosphorylation, and the size of the labeled protein was the same as previously reported for soluble PC-1. PC-1 was also labeled with [alpha-32P]ATP and [35S]dATP[alpha S]. We found no evidence that PC-1 was capable of phosphorylating proteins other than itself, and conclude that it is not a true kinase, and that the observed labeling with [gamma-32P]ATP, [alpha-32P]ATP and [35S]dATP[alpha S] reflect transient covalent adducts that are part of the catalytic cycle of phosphodiesterase/pyrophosphatase activity rather than intrinsic kinase activity. Mutation of the active-site threonine to tyrosine, serine or alanine reduced the 5'-nucleotide phosphodiesterase activity of PC-1 and its ability to autophosphorylate to undetectable levels. Together, these data suggest that both activities depend on the same site.

Biochemical characterization of human PC-1, an enzyme possessing alkaline phosphodiesterase I and nucleotide pyrophosphatase activities.

PC-1 is an ecto-enzyme possessing alkaline phosphodiesterase I and nucleotide pyrophosphatase activities. In this paper, we demonstrate the expression, biochemical characterization and biosynthesis of human PC-1. Previously, there has been uncertainty concerning which of two methionine residues is the initiator. It is now shown that expression of PC-1 is much greater if the first methionine residue is present, and that the sequence between the two methionine residues is translated in both human and mouse, in both transfected cells and cells naturally expressing PC-1. The first methionine residue is therefore the initiator. Human PC-1 is capable of autophosphorylation, and conditions are described in which PC-1 is the only labelled phosphoprotein on the plasma membranes of intact cells, allowing the demonstration that the mature membrane form of human PC-1 is approximately 10 kDa larger than that of the mouse form. Pulse-chase biosynthetic studies and treatment with two different endoglycosidases show that most of this difference is due to N-linked oligosaccharides. The polypeptide backbone of human PC-1 is 20 amino acids longer than that of the mouse PC-1, with most of the difference in polypeptide chain length being in the cytoplasmic domain. The revised cytoplasmic domain of human PC-1 has 76 amino acids, while the mouse cytoplasmic domain has 58 amino acids. Optimal alignment of mouse and human cytoplasmic domains reveals areas of sequence conservation in which the third bases vary. It is suggested that these regions of conservation may point to functionally important sequences in the cytoplasmic domain.

Divalent cations stabilize the conformation of plasma cell membrane glycoprotein PC-1 (alkaline phosphodiesterase I).

The plasma cell-membrane glycoprotein PC-1 is an ectoenzyme with alkaline phosphodiesterase I/5'-nucleotide phosphodiesterase (EC 3.1.4.1) and nucleotide pyrophosphatase (EC 3.6.1.9) activities. It contains sequence motifs which closely match the consensus EF-hand (helix-loop-helix) Ca(2+)-binding regions of parvalbumin, troponin-C and calmodulin, and its enzymic activity is increased in the presence of divalent cations and decreased in the presence of chelating agents. We have undertaken experiments to determine whether divalent cations affect the conformation of the PC-1 protein, as assessed by their effect on thermal stability, resistance to proteolysis and binding of polyclonal antibodies to the whole native protein and monoclonal antibodies to a putative Ca(2+)-binding region. Divalent cations were found to protect solubilized PC-1 against thermal denaturation and proteolysis. They also stabilized PC-1 on intact cells; this form was much more resistant to proteolysis than Triton X-100 solubilized PC-1. Ca2+, Mg2+ and Zn2+ ions were equally effective. Monoclonal antibodies to the bacterially expressed C-terminal EF-hand homology region only bound to mammalian PC-1 in the absence of Ca2+. In contrast, the great majority of polyclonal antibodies to native PC-1 bound regardless of whether Ca2+ was present or not, but with increased binding when Ca2+ was present. These results provide evidence that divalent cations bind to PC-1 and stabilize its conformation.

Identification and characterization of a soluble form of the plasma cell membrane glycoprotein PC-1 (5'-nucleotide phosphodiesterase).

PC-1 is a membrane glycoprotein, found on the surface of plasma cells and a few types of nonlymphoid cells, which has recently been found to have 5'-nucleotide phosphodiesterase activity. In this paper, we demonstrate the existence of enzymically active water-soluble forms of PC-1 in ascites from plasmacytoma-bearing mice, normal mouse serum, and in supernatants of cultured mouse plasmacytoma cells and mouse L cells transfected with a cDNA encoding the membrane form of PC-1. The water-soluble enzyme activity can be specifically immunoprecipitated by a monoclonal antibody to an allotypic determinant on the membrane form of PC-1, and resides on a slightly smaller polypeptide than membrane PC-1. Biosynthetic studies revealed a single, monomeric, endoglycosidase-H-sensitive membrane PC-1 precursor, which was gradually converted to a disulphide-bonded, endoglycosidase-H-resistant form over a period of about 2 h. Soluble PC-1 was first detectable in the supernatant after about 2 h. A distinct intracellular form of soluble PC-1 was not seen. The soluble form of PC-1 does not appear to arise by proteolytic cleavage from the cell surface, although cleavage inside the cell remains a possibility. When taken together with the structure of the relevant portions of PC-1 gene exons, the data suggest that the most likely site of cleavage is between Pro152 and Ala153.