约氏疟原虫配子体形成的形态学特征

应用六氰酸铁钾和锇酸双染色法的透射电镜技术,对红内期疟原虫配子体形成过程中的形态生物学特征进行识别。结果表明,配子体是一渐进发育的单核、惰性(团块样、虫体不活跃)虫体,其核旁有一个由扁平囊和泡状小体极性排列组成的细胞器——高尔基体(Golgi complex),虫体被膜下有嗜锇小体。其雌性配子体的结构特点是核质较致密、内质网丰富和被膜下嗜锇小体多;而雄性配子体却是核质较疏松、线粒体发达、内织网和嗜锇小体少。结论是红内期疟原虫配子体形成与裂体增殖过程中形态结构的明显差别,雌雄配子体在结构与发育上明显的差异,都具有特定的生物学与生态学意义。     

鼠疟原虫蚊期配子生殖的体外培养——在Eagle MEM培养基中发育的观察

为预防疟疾,开展疟原虫生物学、免疫学等方面的研究,从而设想建立疟原虫蚊期(配子生殖、孢子增殖)的体外培养系统。有关鼠疟原虫蚊期配子生殖的体外培养,国内外曾有不少的报道。近年来,国内曾用多种培养基对离体培养鼠动合子进行了初步观察;同时又在鼠疟动合子的形成和离体培养方法上进行了研究;国外学者罗萨利斯-龙奎尔(Rosales-Ronquillo)等在使用含斯氏按蚊细胞原代培养物的Eagle MEM.培养基和鲦鱼上皮细胞系Eagle MEM培养基对离体培养伯氏疟原虫的动合子进行了活体观察;斯皮尔(Speer)也使用了含该种蚊细胞的Eagle MEM培基进行鼠疟     

约氏疟原虫蚊期体外培养：动合子和动合子形成的扫描电镜观察

为了开展疟疾防治以及疟原虫生物学的研究,进一步了解在体外培养中疟原虫的发育规律、形态结构等生物学特性,我们于1985年对离体培养的约氏疟原虫约氏亚种动合子和动合子形成进行了扫描电镜的观察。 材料和方法 约氏疟原虫约氏亚种(Plasmalium yoelii yoelii)用血传和蚊传保种。在昆明株小鼠(KM/AMS)体内多次血传做为供血鼠。C_(57)6JB/ax 小鼠保种。定期感染斯氏按蚊(Anpheles stephensis)MEM     

鼠疟原虫动合子体外培养及其生物学活性的研究

体外形成的动合子能否感染蚊媒并继续在蚊体内发育是评价体外形成动合子发育成熟的重要指标。它关系到动合子-卵囊阶段的体外培养和整个蚊期疟原虫的培养。由于体外形成动合子的培养物中含有大量各阶段的疟原虫,对检验体外形成动合子的生物活性造成一定的困难。为此我们对约氏疟原虫动合子进行培养和分离,并检测了体外形成动合子的生物活性。     

伯氏疟原虫PbPH表达特点和单克隆抗体传播阻断效应研究

制备抗PbPH单克隆抗体(mAb),检测伯氏疟原虫(Plasmodium berghei)PbPH的表达特点和传播阻断能力。主要通过蛋白免疫印迹(Western blot, WB)和间接免疫荧光法(Indirect immunofluoscent assay, IFA),确定PbPH的表达阶段以及抗PbPH单克隆抗体的特异性。1×10~6个P.berghei感染雌性BALB/c小鼠3 d后,尾静脉收集感染小鼠的血液,与鼠源的抗PbPH单克隆抗体/PBS对照,按照不同的稀释倍数(1?5、1?10、1?50)进行混合培养,观察15 min后,伯氏疟原虫配子体出丝中心数及24 h后动合子形成数的变化。WB和IFA检测抗PbPH单克隆抗体可以识别雌雄配子体、雄配子、雌配子/合子、retort和动合子的表面抗原。体外传播阻断实验中,与PBS对照组相比,在加入不同浓度(1?5、1?10)的抗PbPH单克隆抗体培养后,配子体出丝中心数分别减少了41.7%、32.7%,差异具有统计学意义(P0.05);动合子形成数分别减少了45.1%、14.8%,差异具有统计学意义(P0.05)。抗PbPH单克隆抗体可以有效阻断体外配子体出丝中心和动合子的形成,从而影响伯氏疟原虫在蚊体内的进一步发育和继续传播。     

离体培养中鼠疟原虫动合子形成过程形态学的初步观察

近年来国内对鸡疟、猴疟在蚊体内的发育进行了较详细的观察(北京医学院寄生虫学教研组,1978;陈佩惠等,1979),国外也有类似的报告(Bano,1959;Garnham,1966;Yoeli,1965;Yoeli和Most,1960)。1968年Yoeli和Upmanis及Alger相继报告了对鼠疟原虫(P. berghei)配子体到动合子的离体培养以来,国内外学者陆续作了许多工作(Rosales-Ronquillo和Silverman,1974;Rosales-Ronquillo等,1974;Weiss和Venderberg,     

间日疟原虫卵囊内成孢子细胞与子孢子形成的超微结构观察

应用透射电镜观察间日疟原虫在大劣按蚊体内发育的卵囊内成孢子细胞及子孢子形成过程形态变化。疟原虫采自带有配子体的间日疟自愿者。蚊虫在感染后8天作解剖。本研究观察结果与前人所描述的柏氏疟原虫和鸣疟原虫的成孢子细胞与子孢子形成过程相似,即成孢子细胞形成开始于卵囊被膜下的周围出现液泡,而随着膜下液泡增大,逐渐向胞质延伸并联接成裂缝,使胞质再分裂而形成。子孢子周围的膜下微管分布不对称,其数目和排列型式,多数为:7+4、7+5、8+4和8+5,少数为10+1,与前人报告不同(10+1)。     

柔嫩艾美耳球虫配子发生的超微结构

利用透射电镜对柔嫩艾美耳球虫配子生殖阶段的超微结构进行了,大配子体和小配子体于相邻的宿主肠上皮细胞内相产生,由末代裂殖子入后,长大变圆而形成,小配子的形成为直接分化型,首先细胞核分裂成为多核体,随后细胞核向周边移动,然后紧靠细胞处的限制向外突出,临近突出部位的限制膜下陷,在核上方形成中心粒,中心粒发育为基粒,鞭毛中的微管和附着微管,早期形成的小配子仍与小配子体的殖体相连,成熟的小配子与配子体分离,外型香蕉状,外被单位膜,内有一电子结构十分致密的细胞核,核的头端侧面有一个巨大的线粒体,小配子有鞭毛2根,每根鞭毛内有微管,组成为9＋2结构,此外,小配子至少有6根附着微管,大配子体和大配子外被单位膜,内部形成大量的成囊体1和成囊体2,并有大量的支链淀粉和脂肪体,中央有一个细胞核,卵囊臂有5层,细胞核位于细胞中央,细胞内有大量的支链淀粉和脂肪体。     

水蕨卵膜的形成及其超微结构的观察

蕨类植物成熟卵的周围有一层卵膜,但其细微结构和形成过程仍不清楚,本研究应用透射电镜技术对水蕨(Ceratopteris thailictroides)卵细胞发育过程中卵膜的形成及超微结构进行了观察.结果表明水蕨卵细胞在发育中期开始形成卵膜,卵上方的卵膜十分显著,是由多层嗜锇性内质网片层附着于质膜内表面形成的,成熟时卵上方的卵膜中心部分厚,向边缘逐渐变薄,在嗜锇性片层之间填充有嗜锇性物质.比较而言,卵下方及侧面的卵膜薄,由两层紧密连接的嗜锇性膜构成.首次阐明了蕨类植物卵膜形成的超微结构,并对卵膜的一些功能进行了探讨.     

绵马鳞毛蕨精母细胞和游动精子超微结构特征的研究

应用电镜技术对蕨类植物绵马鳞毛蕨(RYOPTERIS CRASSIRHIZOMA Nakai)精母细胞和游动精子的超微结构特征进行了研究。精母细胞为多边形,细胞质内含有丰富的线粒体、质体、内质网、高尔基体等常见的细胞器．在细胞质中还可见到一些同心圆膜状结构,位于质膜的附近或精母细胞的角偶。同心圆膜状结构由双层膜环绕构成,外被l层单位膜。精母细胞与精子器的璧细胞之间形成了分离腔。在精母细胞质膜外形成了嗜锇层,这些结构的形成说明精母细胞已经开始与雄配子体逐渐分离,进入独立发育的阶段。尽管精母细胞之间也有嗜锇层的形成,但嗜锇层是不连续的,其上有一些空隙,精母细胞之间可通过空隙进行物质和信息的交流。成熟的精子细胞外被l层透明的薄膜,里面为游动精子。螺旋状。由环状细胞器环绕3～4圈构成．这些环状细胞器包括多层结卡构、微管带、巨大线粒体、鞭毛带和1个长形浓缩的细胞核。游动精子的后端为一些泡囊化的细胞质．其中包括一些残存的线粒体、造粉质体及大的囊泡等。当成熟的精子细胞排出精子器后。其内的游动精子挣脱透明质膜的束缚,摆脱后端的囊泡,成为1条游动精子。本文还对绵马鳞毛蕨和其它蕨类植物精子的超微结构特征进行了比较。     

Gametogenesis, fertilization and ookinete differentiation of Leucocytozoon smithi

Development of Leucocytozoon smithi during gametogenesis, fertilization, and ookinete differentiation was studied by light and electron microscopy. Gametogenesis occurred rapidly, within 1-2 min after gametocytes were ingested by black flies. Usually one axoneme, but not infrequently two, was observed in microgametes. The macrogamete nucleus was characteristically elongated and fragmented, with a convoluted nuclear envelope. Fertilization occurred within five min after ingestion of gametocytes by the vector. The entire axoneme and nucleus of the microgamete entered the cytoplasm of the macrogamete. Zygote differentiation resembled sporozoite formation in that a thickened inner membrane and subpellicular microtubules developed beneath the plasmalemma, followed by cytoplasmic protrusion or evagination to form the anterior end. Extension of the inner thickened membrane continued as the zygote elongated. Development of sausage-shaped ookinetes was completed within 6-8 h after ingestion of a blood meal by a black fly. Mature ookinetes possessed a single nucleus, double-layered pellicle, canopy, apical pore, polar ring complex, subpellicular microtubules, micronemes, crystalloids, abundant mitochondria, endoplasmic reticulum, and ribosomes. Comparison of development of L. smithi with species of Plasmodium and Haemoproteus revealed general similarities in both sexual and asexual development within the insect vector. A diagram summarizing life cycle events for L. smithi is included.     

Fine Structure of Haemoproteus columbae Kruse During Differentiation of the Ookinete*

Ookinete differentiation begins in vitro～1 hr after blood infected with mature gametocytes of Haemoproteus columbae is withdrawn from a pigeon. In the undifferentiated zygote, dense material accumulates at the point under the plasma membrane. The conoid and conoidal rings condense from this material. The nucleus is drawn out to a point with the intranuclear spindle (INS) at the peak. Atypical centrioles lie under the forming conoid in the cytoplasm next to the INS. Fibrous material under the inner membrane forms the polar ring from which subpellicular microtubules originate. One hr later the centrioles have disappeared and the nucleus has returned to the center of the organism. The conoidal complex forms the tip of a growing cytoplasmic projection, the anterior end of the ookinete. During this time an elaborate pellicle is differentiating antero-posteriorly; crystalloid formation begins with an extensive proliferation of rough endoplasmic reticulum (ER) continuous with the outer membrane of the nuclear envelope. Crystalloid particles are formed between the lamellae of the ER and collected in a sphere that is later partially surrounded by a small amount of ER. Ookinetes, differentiated 2 hr longer than the ookinetes in vitro, were obtained from the gut of the pigeon fly, Pseudolynchia maura. The differentiated pellicle of these ookinetes consists of a plasma membrane, an inner membrane layer composed of 2 appressed membranes, and in the anterior end, an electron-opaque lamina immediately under the inner membrane. Anterior to the polar ring, this lamina forms a canopy which, posteriorly, is drawn out into projecting ribs which diminish and disappear in the first third of the organism. Fifty to 60 subpellicular microtubules insert on the polar ring. Ookinetes differentiated in vitro were no more than 4 hr old. They lacked micronemes and retained a pellicular cytostome and “internal cytostomes.” The differentiation of micronemes probably occurs at a later time because they are visible after 6 hr in ookinetes in the fly gut. So many degenerating organisms appeared in vitro after 5 hr that this material was discarded.     

New Observations on Gametogenesis,Fertilization, and Zygote Transformation in Plasmodium gallinaceum1

The ultrastructure of the sexual stages of Plasmodium gallinaceum during gametogenesis, fertilization, and early zygote transformation is described. New observations are made regarding the parasitophorous vacuole (PV) of gametocytes and the process of emergence in male and female gametocytes. Whereas female gametocytes readily disrupted both the PV membrane and host cell plasmalemma during emergence, male gametocytes frequently failed to break down the plasmalemma of the host cell. New observations and hypotheses are presented on the behavior of the male gamete nucleus. Following fertilization, the male nucleus appears to travel through a channel of endoplasmic reticulum in the female gamete before fusing with the female nucleus at a region in which the nuclear envelope is thrown into extensive convoluted folds. Polarization of the zygote nucleus, in association with the appearance of a perinuclear spindle of cytoplasmic microtubules, preceded all other changes in the developing zygote. After nuclear polarization becomes apparent, electron-dense material is deposited beneath the zygote pellicle, and a canopy is formed which eventually extends over the entire apical end of the developing ookinete. As the apical end begins to extend outward, polar rings, micronemes, and subpellicular microtubules become visible in this portion and a “virus-like” inclusion known as a crystalloid is formed in the posterior portion of the zygote. When female gametes are prevented from being fertilized, the cytoplasm at 24 h after gametogenesis is devoid of most of those organelles found in the developing zygote or the mature ookinete. The cell is surrounded only by a single membrane. Although at various points beneath the membrane there are deposits of electron-dense material reminiscent of those deposited in the zygote, no further development of ookinete structures takes place in the unfertilized female gamete.     

The Fine Structure of Haemoproteus columbae Sporozoites*

SYNOPSIS. The fine structure of Haemoproteus columbae sporozoites has been studied and compared to sporozoite structure as revealed by the light microscope. The sporozoites are ultrastructurally similar to those of other Haemosporidia in that they possess a 3-layered pellicle, subpellicular microtubules, polar ring, micropore, free ribosome-like particles, micronemes, a structure resembling a Golgi complex, an irregular mitochondrion, and a large nucleus. In the anterior region of the sporozoite there are 21–22 regularly arranged longitudinal subpellicular microtubules located peripherally around the cell. In the apical region the microtubules appear thickened on 1 side. The sporozoite of H. columbae has a microneme system in which 1–3 micronemes are associated with the outer pellicular membrane at the anterior end. Micronemes are found throughout the cytoplasm, but occur in greater concentration in the anterior region of the sporozoite. A clear pellicular cavity, located between the polar ring and the termination of the inner pellicular layer, is present at the anterior end of the sporozoite. Vesicular invaginations of the inner pellicular layer have been observed in the anterior region; their function is unknown. Spherical osmophilic bodies are found throughout the cytoplasm.     

Early Stages in the Differentiation of Gametocytes of Haemoproteus columbae Kruse*

SYNOPSIS The sexes of mature gametocytes of Haemoproteus columbae Kruse circulating in the blood of the domestic pigeon can be identified in the electron microscope by the same criteria that distinguish them in the light microscope. The microgametocyte has a large nucleus and pigment granules restricted to the 2 extremities of its halter-shaped cells. The macrogametocyte has dense granular cytoplasm with scattered pigment granules and a small central nucleus. The sex of young gametocytes cannot yet be recognized. When blood containing mature gametocytes is cooled outside the body of the host visible signs of gametogenesis appear within 30 seconds. The earliest signs are increasing electron lucidity of the cytoplasm and separation of the outer membrane from the body of the parasite. The membrane may form vesicles or whorls or lie free in the erythrocyte's cytoplasm. The middle membrane of the parasite becomes the plasma membrane. Axonemes and microtubules appear in the cytoplasm and nucleoplasm of the microgametocyte. The macrogametocyte lags slightly behind the microgametocyte in development. With the first signs of differentiation, the host cell cytoplasm begins to disappear. The fate of the outer membrane and the erythrocyte's cytoplasm suggests the release of a lytic substance by the parasite.     

Gametocyte Maturation,Exflagellation and Fertilization in Parahaemoproteus (=Haemoproteus) velans (Coatney & Roudabush) (Haemosporidia: Haemoproteidae): an Ultrastructural Study*

SYNOPSIS. The structural changes in macro and microgametocytes of Parahaemoproteus velans following removal of infected blood from the avian host were studied in the light and electron microscope. Gametocytes of both sexes round up and soon escape from their host cells. Shortly thereafter they assume a dumbbell shape. The microgametocyte undergoes exflagellation forming 8 slender microgametes. During fertilization the entire microgamete appears to enter the female. The most striking ultrastructural change in the formation of the macrogamete is the condensation and enclosure by a membrane of abundant amophorus dense material seen in the cytoplasm of the immature gametocyte. Maturation of the microgametocyte begins prior to its escape from the host cell. Axonemes are present in the cytoplasm and nuclear reorganization occurs while the parasite is intracellular. Bundles of microtubules associated with condensed chromatin are found in the peripheral cytoplasm of maturing forms and apparently participate in the formation of small compact microgamete nuclei. Each of these filiform structures consists of a dense, centrally located nucleus and a single axoneme lying in flocculent cytoplasm. The nucleus and axoneme of the microgamete are seen free in the cytoplasm of a fertilized macrogamete.     

The Fine Structure of the Macrogametocytes of Adelina tribolii Bhatia, 1937 (Eucoccidia, Telosporea) from the Fat Body of the Beetle Tribolium castaneum Hbst.

SYNOPSIS. Macrogametocytes of the coccidium Adelina tribolii Bhatia, 1937 are described from the time when they settle in the fat body of the host and form periparasitic vacuoles around them to the stage of microgametocyte occurrence and the beginning of syzygy formation.
The macrogametocyte is surrounded by a 2-layered pellicle 50 mμ thick. Its continuity is interrupted by one or several micropores 40 mμ across and 86 mμ deep.
The cytoplasm of the parasite contains numerous vesicles and lamellae of rough and smooth endoplasmic reticulum. Mitochondria of various sizes have short tubules. The macrogametocyte contains a variable number of dark bodies 1.4-2.4 μ in diameter. It also contains several vacuoles up to 1.2 μ which are covered with a 3-layered membrane and enclose a granular material.
In old macrogametocytes in syzygy multivesicular bodies develop which measure up to 2.4 by 1.6 μ. Several smaller vacuoles containing granular material are also a constituent of the electrondense basic substance of these corpuscles.
Paraglycogen granules 1.4 by 0.9 A occur in old macrogametocytes and are situated inside the vacuoles which are not bordered by a membrane. The numbers and size of these granules increase with the age of the parasite. The Golgi complex lies close to the nucleus.
The nucleus, 6-8.5 μ in diameter, is in the center of the macrogametocyte and contains a large eccentric nucleolus. The nuclear membrane is 2-layered and has many pores.     

Development of Plasmodium berghei ookinetes to young oocysts in vitro.

The mosquito stage of Plasmodium berghei was cultivated in vitro, with special attention to ookinete transformation into early oocyst. The ookinetes were obtained by in vitro culture of gametocytes taken from infected mice, purified by density gradient of metrizoic acid or a lymphocyte separation medium, and incubated either in acellular culture or in co-cultivations with mosquito cells. In acellular culture, the ookinetes were found to aggregate with each other and transformed from banana to round shapes. Their inner pellicular membranes and subpellicular microtubules partially disappeared, indicating that development to early oocyst had occurred. Co-cultivation wtih Aedes albopictus cells (C6/36 clone) revealed that ookinetes transformed into early oocyst in the medium, or invaded the cells and then transformed to early oocysts within the cell cytoplasm as well. However all of these transformed cells failed to develop further, i.e., neither deposition of the oocyst capsule nor nuclear division was observed. Many ookinetes which failed to penetrate the Aedes cells were phagocytized within three days of culture. A significant difference between invaded and transformed oocysts and phagocytized ookinetes was seen in that the former lacked vacuole membrane. Co-cultivation with Toxorhynchites amboinensis cells (TRA-284-SFG clone) permitted transformation of ookinetes into early oocysts in the medium as in the acellular culture, but no ookinete invasion nor phagocytosis by the cell was observed.     

The Ultrastructural Aspect of Tapetum and Ubisch Bodies in Anemarrhena asphodeloides

From ontogeny of tapetum in Anemarrhena asphodeloides, the ultrastructnral features of tapetal cells are as follows: 1. The profuse rough endoplasmic reticula are often closely associated with lipid bodies and vesicles, and linking each other into compound organelles. This is one of the striking features in Anemarrhena tapetal cell. 2. After meiosis of the micro- spore mother cell, the tapetal cytoplasm contains a large number of vesicles, in which the electron opaque substances are accumulated. Then they fuse to form a large zone of storage material similar to lipid bodies. Before accumulation of opaque material, these vesicles in the tapetal cytoplasm are larger than those in elaioplast (see Plate II, Fig. 2). 3. During stage of pollen maturation the tapetal cytoplasm becomes disorganized and the cells are almost occupied by the elaioplasts at various degree of development. On the basis of the report of Dickinson (1973), the formation of a pollen coatings of Lilium is different from that of Raphanus. The osmiophilic bodies in the former have originated from membrane lamellae or membranous system of plastid, and those in the latter are formed from the plastid vescles. It is intereting to note that the mode of origin of the plastid osmiophilic bodies in Anemarrhena is rather similar to that of Raphanus than to Lilium. About the origin of the pro-Ubisch bodies in tapetal cytoplasm of Anemarrhena studies revealed that a large number of the medium electron dense bodies appear in the tapetal cytoplasm. This is the first sign of the formation of the pro-Ubisch bodies and its character is very similar to spherosome in many respects. From many ultrasections, it can be seen that the ER profile is closely associated with the pro-Ubisch bodies. Thus we can conclude that the proubisch bodies of Anemarrhena are derived from rough endoplasmic reticulum. Although Heslop-Harrison et al. (1969) has considered that the compound Ubisch bodies do not occur in Lilium, there are prominent aggregation of Ubisch bodies in Anemarrhena, same as reported in Oxalis (Cariel, 1967), Silene (Heslop-Harrison, 1963a) and Helleborus (Echlin et al., 1968). After investigation on certain angiosperm in 1972, Gupta and Nanda have reported that the peritapetal membrane belonging to tapetum of secretory type lies against the inner tang- ential wall; in the plasmodial type of tapetum, it is formed on the outer tangential wall. But in some species of Poaceae and Solanaceae, the peritapetal membrane is formed on both sides of the tapetal cells (Banerjee, 1967; Reznickov & Willemse, 1980). In the secretory tapetum of Anemarrhena, the peritapetal membrane, which do not comply with the conclusion of Gupta & Nanta (1972), is formed on outer tangential wall.     

Fine Structure of Gametogony and Oocyst Formation in Sarcocystis sp. in Cell Culture

Fine structure of gametocytes and oocyst formation of Sarcocystis sp. from Quiscalus quiscula Linnaeus grown in cultured embryonic bovine kidney cells was studied. Microgametocytes measured up to ～5 μm diameter. During nuclear division of the microgametocyte, dense plaques were found adjacent to the nucleus just beneath the pellicle; occasionally microtubules were present within these plaques. These microtubules subsequently formed 2 basal bodies with a bundle of 4 microtubules between them. Microgametocytes also contained numerous mitochondria, micropores, granules, vacuoles, and free ribosomes. Each microgamete was covered by a single membrane and consisted of 2 basal bodies, 2 flagella, a bundle of 4 microtubules, a perforatorium, a mitochondrion, and a long dense nucleus which extended anteriorly and posteriorly beyond the mitochondrion. The bundle of 4 microtubules is thought to be the rudiment of a 3rd flagellum. Macrogametes were covered by a double membrane pellicle, and contained a large nucleus (～2.5 μm), vacuoles, and a dilated nuclear envelope connected with the rough endoplasmic reticulum (ER). In young macrogametes (～4 μm), the ER was arranged in concentric rows in the cortical region, and several sizes of dense granules were found in the cytoplasm. However, in later stages (～8 μm) the ER was irregularly arranged and was dilated with numerous cisternae; only large dark granules remained and a few scattered polysaccharide granules were found. No Golgi apparatus or micropores were observed. After the disappearance of dark granules 5 concentric membranes appeared. Four of these fused to form an oocyst wall composed of a dense outer layer (～66 nm thick) and a thin inner layer (～7 nm). The 5th or innermost membrane surrounded the cytoplasmic mass which was covered by a 2-layered pellicle and contained a nucleus, small amounts of ER, large vacuoles, and mitochondria. The sexual stages described greatly resemble those of Eimeria and Toxoplasma.