Modulation of linker histones during development in Tetrahymena: selective elimination of linker histone during the differentiation of new macronuclei.

Macronuclei of Tetrahymena thermophila contain a typical H1 which has been shown to be missing from micronuclei. Instead, micronuclei contain three unique polypeptides, alpha, beta, and gamma, which are associated with linker regions of micronuclear chromatin. In this report polyclonal antibodies raised against macronuclear H1 are shown to react with alpha, beta, and gamma by immunoblotting analyses. This result suggests that these polypeptides share some common structural feature(s). Also consistent with this result is the finding that both macro- and micronuclei in growing and mating cells stain positively with H1 antibodies by in situ indirect immunofluorescence. However, these analyses demonstrate that the level of linker histone is greatly reduced in the micronucleus of starved cells and in young macronuclear anlagen. These results are in agreement with earlier biochemical studies and together provide strong evidence that dramatic changes in linker histone accompany nuclear differentiation (and dedifferentiation) in Tetrahymena.

Proteolytic processing of h1-like histones in chromatin: a physiologically and developmentally regulated event in Tetrahymena micronuclei.

Micronuclei isolated from growing cells of Tetrahymena thermophila contain three H1-like polypeptides alpha, beta, and gamma. Micronuclei isolated from young conjugating cells (3-7 h) also contain a larger molecular weight polypeptide, X, which is being actively synthesized and deposited into these nuclei (Allis, C. D., and J. C. Wiggins, 1984, Dev. Biol., 101:282-294). Pulse-chase experiments (with growing and conjugating cells) suggested that X is a precursor to alpha and that alpha is further processed to gamma and a previously undescribed and relatively minor species, delta. These precursor-product relationships were supported by cross-reactivity with polyclonal antibodies raised against alpha and peptide mapping. While beta consistently became labeled under chase conditions (both in growing and mating cells), it was not clear whether it is part of the vivo processing event(s) which interrelates X, alpha, gamma, and delta. Beta was not recognized by alpha antibodies. Despite this uncertainty, these results suggest that proteolytic processing serves to generate significant changes in the complement of H1-like histones present in this nucleus.

Proteolytic processing of micronuclear H3 and histone phosphorylation during conjugation in Tetrahymena thermophila.

During vegetative growth, micronuclei of the ciliated protozoan Tetrahymena thermophila contain two electrophoretically distinct forms of H3, H3S and H3F [4, 5]. Of these two forms, H3F is unique to micronuclear chromatin and is derived from H3S by a physiologically regulated proteolytic processing event [5]. While the function of this processing event is not clear, several lines of evidence [2, 5] suggest that it may be related to chromatin condensation during mitosis. In this report pulse-chase experiments have been used to study the processing of H3S into H3F during the sexual phase of the life cycle, conjugation. Our results demonstrate that even though micronuclei divide mitotically (and meiotically) several times during the mating process, processing of H3S into H3F does not occur. Failure of H3S to be converted into H3F during these divisions causes a significant increase in the amount of H3S (relative to H3F) as conjugation proceeds. By 10 h of conjugation, essentially all of the micronuclear H3 is in the form of H3S (also see [3]). As long as mating cells are maintained under starvation conditions, processing of H3S into H3F does not occur. However, if exconjugants are returned to food and allowed to proceed through the first true cell division following exconjugation, processing of H3S into H3F occurs. Thus, the return of the processing of H3(3) into H3F following conjugation seems to be tightly coupled to a division which is part of a cell division cycle (as appears to be the case with vegetatively growing cells). The relevancy of these results to the differentiation of new macro- and micronuclei is discussed. H3F is specifically phosphorylated in growing cells, and it has been suggested that this phosphorylation event may be related to chromatin condensation during mitosis [2]. Since in mating cells H3S becomes the more predominant form of H3, the pattern of histone phosphorylation was examined during stages of conjugation where micronuclei are active in mitotic division (6-7 h). While a low level of phosphate label is observed over H3S in mating cells, more phosphate label is associated with the small amount of H3F which remains in micronuclei at this stage of conjugation. We also observe significant amounts of phosphate label associated with micronuclear H2A, H2B, and H4 and each of the micronuclear H1-like molecules, alpha, beta and gamma.

Histone rearrangements accompany nuclear differentiation and dedifferentiation in Tetrahymena.

Histone synthesis and deposition into specific classes of nuclei has been investigated in starved and conjugating Tetrahymena. During starvation and early stages of conjugation (between 0 and 5 hr after opposite mating types are mixed), micronuclei selectively lose preexisting micronuclear-specific histones alpha, beta, gamma, and H3F. Of these histones, only alpha appears to accumulate in micronuclear chromatin through active synthesis and deposition during the mating process. Curiously, alpha is not observed (by stain or label) in young macronuclear anlagen (4C, 10 hr of conjugation). Thus, young macronuclear anlagen are missing all of the histones which are known to be specific to micronuclei of vegetative cells. By 14-16 hr of conjugation, we observe active synthesis and deposition of macronuclear-specific histones, hv1, hv2, and H1, into new macronuclear anlagen (8C). Thus macronuclear differentiation seems well underway by this time of conjugation. It is also in this time period (14-16 hr) that we first detect significant amounts of micronuclear-specific H1-like polypeptides beta and gamma in micronuclear extracts. These polypeptides do not seem to be synthesized during this period, which suggests that beta and gamma are derived from a precursor molecule(s). Since these micronuclear-specific histones do not appear in micronuclear chromatin until after other micronuclei have been selected to differentiate as macronuclei, we suspect that micronuclear differentiation is also an important process which occurs in 10-16 hr mating cells. Our results also suggest that proteolytic processing of micronuclear H3S into H3F (which occurs in a cell cycle dependent fashion during vegetative growth) is not operative during most if not all of conjugation. Thus micronuclei of mating cells contain only H3S which also seems consistent with the fact that some micronuclei differentiate into new macronuclei (micronuclear H3S is indistinguishable from macronuclear H3). Interestingly, the only H3 synthesized and deposited into the former macronucleus of mating cells is the relatively minor macronuclear-specific H3-like variant, hv2. These results demonstrate that significant histone rearrangements occur during conjugation in Tetrahymena in a manner consistent with the fact that during conjugation some micronuclei eventually differentiate into new macronuclei. Our results suggest that selective synthesis and deposition of specific histones (and histone variants) plays an important role in the nuclear differentiation process in Tetrahymena.

Investigation of the relation of the pH-dependent dissociation of malate dehydrogenase to modification of the enzyme by N-ethylmaleimide.

The pH-dependent dissociation of porcine heart mitochondrial malate dehydrogenase (L-malate:NAD+ oxidoreductase, EC 1.1.1.37) has been further characterized using the technique of sedimentation velocity ultracentrifugation. The increased rate and specificity of the inactivation of mitochondrial malate dehydrogenase by the sulfhydryl reagent N-ethylmaleimide has been correlated with the pH-dependent dissociation of the enzyme. Data obtained using NAD+ and its component parts to reassociate the enzyme and also to protect the enzyme from inactivation by N-ethylmaleimide suggest that the sulfhydryl residues being modified by N-ethylmaleimide are inaccessible when the enzyme is in its dimeric form. A dissociation curve for the pH-dependent dissociation suggests that a limited number of residues are being protonated concomitant with dissociation of the enzyme. An apparent pKa of 5.3 has been determined for this phenomenon. Studies using enzyme modified by the sulfhydryl reagent N-ethylmaleimide indicate that selective modification of essential sulfhydryl residues alters the proper binding of NADH.