Morphology and anatomy Spirostomum is a medium to large worm-like (vermiform) elongated ciliate, ranging from around 150 μm to 4 mm and is large enough to be confused with small
helminths. It moves by gliding slowly over or swimming freely above the substrate. It possesses tubular or somewhat flattened bodies, with colours ranging from a faint brown or yellow, to green. The organism is bound externally by a thin layer of ectoplasm while the endoplasm consists of large vacuoles separated by a mesh of fluid protoplasm. Cells are often hosts of prokaryotic and eukaryotic symbionts. A single contractile vacuole is positioned at the posterior end of the organism, attached to a collecting canal that extends towards the anterior end. When filled with fluid, the vacuole takes up a substantial portion of the posterior end. The distinction between the contractile vacuole and the rest of the cytoplasm is usually very clear. The number of
micronuclei vary, but they are either ovoid or ellipsoid in shape and are usually located near the macronuclei. For “single” type macronuclei, there are depressions for the micronuclei, thus resulting in overlapping. Information regarding
S. caudatum and
S. semivirescens is minimal as there is a lack of knowledge and research on these two species. Please note that these findings are based on the specimens observed by the researchers mentioned and thus, when observing the description of organisms in other primary literature, there may be slight differences between the numbers mentioned in this table and the numbers observed in other articles. Both should be considered true as these ranges can be adjusted to include smaller or larger organisms in the various species.
Life cycle Ciliates generally have two forms of reproduction. They are able to reproduce asexually through division via
fission and sexually through conjugation. During fission, it is observed that the micronucleus divides mitotically before the cell separates into daughter cells. Micronuclei divide amitotically. On the other hand, during conjugation, the macronucleus is reabsorbed, and the micronuclei perform meiosis. For the genus
Spirostomum, most of these characteristics are observed. The following descriptions of the reproduction processes are based on observations made of
Spirostomum ambiguum, the most investigated species in the genus. Asexual division begins with the formation of the peristomal membranelle, AZM, of the new cytostome, indicated by the slight ridge in the posterior end of the specimen which eventually becomes more pronounced. Then, the macronucleus straightens out and loses its lobation, becoming vermiform (like a worm). The macronucleus contracts and thickens, resulting in contracted macronucleus positioned in the anterior end of the organism, before rapidly moving to the middle. The contractile vacuole begins splitting to form the daughter contractile vacuole. The macronucleus begins to elongate, with less of it being in the anterior end, and the cell begins separating slightly below the location of the anterior cytostome. The macronucleus divides before the cell divides, forming two daughter cells. Conjugation, the sexual stage, begins with the attachment of the cells together. The conjugates are attached either at or close to the anterior end of both cells. Conjugants are almost always similar in size. Both conjugants are attached from the apex, along the oral groove, to the cytostome by a thin sheet of ectoplasm. Because they are attached like this, it is impossible to feed during conjugation. It is noted that ingestion stops prior to conjugation as indicated by the rare amounts of ingested food found in the cytoplasm during the process. The micronuclei begin to swell, slowly moving away from the macronucleus. Then the moniliform macronucleus beings breaking up into isolated segments, at the points where the nodes were previously connected. Most of the segments move towards the anterior end of the cell, as do most of the enlarged micronuclei which position themselves between the macronuclei nodes. Then the micronuclei undergo
meiosis first producing four daughter nuclei. Three of the daughter nuclei disappear while the fourth one undergoes
mitosis and produces two haploid gametic nuclei. Reciprocal exchange occurs, the gametic nuclei fuse together, and then the conjugants separate. The duration from attachment to separation takes around 60–72 hours. The fused nuclei, called the synkaryon, divides twice into four daughter nuclei. Two of these nuclei fuse and elongate, then form a moniliform macronucleus. The other two nuclei become micronuclei. Some variations may occur in this process, such as the formation of six daughter nuclei to account for the different numbers of micronuclei in each specimen. Other than its reproduction and growth phases,
Spirostomum does not possess any other distinct stages in its life cycle.
Genetics The ability to adapt in hypoxic (low oxygen) or anoxic (no oxygen) habitats in an important aspect in protozoan ecology.
Spirostomum has demonstrated their capability of living in these environments and the reason may be linked some genes they possess. Mukhtar et al. (2021) suggested that the rhodoquinol dependent pathway that had been previously reported in multiple heterotrichs could be responsible for the ability to survive in these conditions. By performing RNA sequencing and analyzing the data for the presence of
rquA, a gene responsible for the synthesis of rhodoquinone (RQ), the presence of this pathway in
Spirostomum could be investigated. This gene was used since its product, rhodoquinone, is an important cofactor in the fumarate reductase pathway. The species
S. ambiguum,
S. teres, and
S. subtilis were collected from a freshwater pond for this study. Based on the analysis of the transcriptome, two or three RquA proteins were found in the species, providing evidence of the existence of the rhodoquinol dependent fumarate reduction pathway in these organisms. In another study, two
Spirostomum species,
S. semivirescens and an unidentified one, were also found to have the gene. The presence of the gene in the four species suggests that this anaerobic respiration pathway is present in the entire genus. == Practical importance ==