Using a Hand-Held Gene Gun for Genetic Transformation of Tetrahymena thermophila.

Biolistic bombardment is widely used as a means of delivering vector-coated microparticles into microorganisms, cultured cells, and tissues. The first particle delivery system contained a helium propulsion unit (the gun) mounted in a vacuum-controlled chamber. In contrast, the hand-held gene gun does not operate within a chamber. It is completely hand-held, easy, and efficient to use, and it requires minimal space on the laboratory bench top. This chapter describes protocols for using a hand-held gene gun to deliver transformation vectors for overexpression of genes or gene replacement into the macronucleus of Tetrahymena thermophila. The protocols provide helpful information for preparing Tetrahymena for biolistic bombardment, preparation of vector-coated microcarriers, and basic gene gun operating procedures.

MyTH4, independent of its companion FERM domain, affects the organization of an intramacronuclear microtubule array and is involved in elongation of the macronucleus in Tetrahymena thermophila.

Myo1 is a class XIV Tetrahymena myosin involved in amitotic elongation and constriction of the macronucleus into two subnuclei at cell division. Elongation of the macronucleus is accompanied by elongation of an intramacronuclear microtubule array, which is oriented parallel to the axis of nuclear elongation. Elongation of the macronucleus often fails to occur or is only partially completed in a MYO1 knockout, and division of the macronucleus is frequently uncoupled from cytokinesis. Myo1 contains a myosin tail homology 4 (MyTH4) and a band 4.1, ezrin, radixin, moesin homology (FERM) domain. Recently, we used green fluorescent protein (GFP) fusions to demonstrate that the entire FERM domain, independent of MyTH4, is essential for localization of FERM to the cytoskeleton and does not appear to directly affect nuclear division. Antiactin coprecipitates GFP-FERM, tubulin, actin, and Myo1. The immunoprecipitated GFP-FERM cosediments with either exogenous F-actin or exogenous microtubules. Here, we show that overexpressed GFP-MyTH4 colocalized with antitubulin to intramacronuclear microtubules. Ninety percent of overexpressing cells assembled intramacronuclear microtubules that did not become organized into a parallel array. Amitosis did not advance in the absence of the parallel array of intramacronuclear microtubules. Five percent of overexpressing cells organized the parallel array, but the microtubules and the macronucleus did not achieve full elongation. Partially elongated macronuclei constricted without cytokinesis. Antiactin coprecipitated GFP-MyTH4, tubulin, and actin. AntiGFP pulled down GFP-MyTH4, tubulin, and actin. GFP-MyTH4 cosedimented with either exogenous microtubules or exogenous F-actin. A novel finding from this study is that MyTH4 and FERM have overlapping and distinct roles in the function of a myosin.

A FERM domain in a class XIV myosin interacts with actin and tubulin and localizes to the cytoskeleton, phagosomes, and nucleus in Tetrahymena thermophila.

Previous studies have shown that Myo1(myosin class XIV) localizes to the cytoskeleton and is involved in amitosis of the macronucleus and trafficking of phagosomes. Myo1 contains a FERM domain that could be a site for interaction between Myo1 and the cytoskeleton. Here, we explore the function of FERM by investigating its cytoskeleton binding partners and involvement in localization of Myo1. Alignment of Myo1 FERM with a talin actin-binding sequence, a MAP-2 tubulin-binding sequence, the radixin FERM dimerization motif, and the SV40 nuclear localization sequence (NLS) revealed putative actin- and tubulin-binding sequences, a putative FERM dimerization motif, and NLS-like sequences in both the N-terminal and C-terminal regions of Myo1 FERM. Alignment of Myo1 with an ERM C-terminal motif revealed a similar sequence in the Myo1 motor domain. GFP-FERM and two truncated FERM domains were separately expressed in Tetrahymena. GFP-FERM contained the entire Myo1 FERM. Truncated Myo1 FERM domains contained either the N-terminal or the C-terminal region of FERM and one putative sequence for actin-binding, one for tubulin-binding, a putative dimerization motif, and a NLS-like sequence. Actin antibody coprecipitated GFP-fusion polypeptides and tubulin from lysate of cells expressing GFP-fusions. Cosedimentation assays performed with either whole cell extracts or anti-actin immunoprecipitation pellets revealed that F-actin (independent of ATP) and microtubules cosedimented with GFP-fusion polypeptides. GFP-FERM localized to the cytoskeleton, phagosomes, and nucleus. Truncated GFP-FERM domains localized to phagosomes but not to the cytoskeleton or nucleus.

MY01, a class XIV myosin, affects developmentally-regulated elimination of the macronucleus during conjugation of Tetrahymena thermophila.

BACKGROUND INFORMATION: Nuclear dimorphism is characteristic of ciliated protozoa. A transcriptionally-active macronucleus co-exists with a transcriptionally-silent micronucleus, which is activated only at conjugation. During conjugation, each conjugant develops two new genetically matched macronuclei and micronuclei, and the pre-existing macronucleus is eliminated. Elimination of the pre-existing macronucleus during conjugation is an apoptotic-like process. The macronucleus becomes highly condensed, DNA laddering occurs, caspase activity increases, acidic enzymes accumulate within the nucleoplasm, and the nucleus shrinks in size. The current study focused on the involvement of actin and myosin in nuclear events of conjugation. A myosin knockout strain was mated with wild-type, and the nuclear events were monitored with confocal microscopy. RESULTS: Early nuclear events, including development of new macronuclei and micronuclei, appeared qualitatively normal in knockout conjugants. Completion of nuclear condensation and acidification in the pre-existing macronucleus was blocked in 44% of knockout conjugants. Knockout conjugants that failed to fully achieve nuclear condensation and acidification did not eliminate the pre-existing macronucleus. In control experiments, blockage of chromatin condensation, nuclear acidification, and macronuclear elimination was never observed in wild-type conjugants. CONCLUSIONS: Perturbation of either DNA fragmentation, chromatin condensation or nuclear acidification can lead to blockage of apoptotic-like elimination of the macronucleus in MYO1-knockout conjugants. Consistent with the known motor function of myosins and the involvement of Myo1 in vesicle trafficking in Tetrahymena, we argue that Myo1 could specifically affect condensation of chromatin and acidification of the nucleus through direct interaction with chromatin and through Myo1-dependent vesicle trafficking to the nucleus.

Myo1 localizes to phagosomes, some of which traffic to the nucleus in a Myo1-dependent manner in Tetrahymena thermophila.

Myo1 is one of 13 myosins in Tetrahymena thermophila. Initially, twelve of the myosins in Tetrahymena were assigned to Class XX in the myosin superfamily but recently re-assigned to a subclass within Class XIV. In a previous study, we reported that genomic knockout of MYO1 affected phagocytosis and macronuclear amitosis. These two phenotypes have appeared disparate because a possible mechanism linking phagocytosis and amitosis was unknown. In the present study, Myo1 localization was investigated in order to further link machinery for phagocytosis and amitosis. Antibodies directed against the Myo1 motor domain detected an immunospecific polypeptide at 175-180 kDa on immunoblots of wild-type proteins. The 175-180 kDa polypeptide was not detected on immunoblots of proteins from the knockout strain. For immunofluorescence microscopy, cells were allowed to internalize fluorescent beads as markers for phagosomes. In wild-type cells, anti-Myo1 and anti-actin antibodies co-localized to the periphery of phagosomes and the macronucleus. In the MYO1-knockout strain only background fluorescence was observed with anti-Myo1 antibody. Confocal x-z series through macronuclei revealed fluorescent beads within the nucleoplasm. Statistical analysis showed a significant difference between the mean distributions of fluorescent beads in the nucleoplasm of wild-type and MYO1-knockout cells. A fluorescent dye was used to label plasma membrane in living cells. Dye-labeled vacuoles trafficked to the macronucleus. Trafficking of phagosomes to the macronucleus in a myosin-dependent manner is a novel finding and a possible mechanism for targeting myosin and actin to the nucleus.

Directed motility of phagosomes in Tetrahymena thermophila requires actin and Myo1p, a novel unconventional myosin.

The phagosome cycle was investigated in Tetrahymena thermophila, which had internalized fluorescent latex beads. Confocal microscopy of cells from a GFP-actin strain revealed actin filaments that extended 3-5 mum from the periphery of fluorescent phagosomes. In GFP-actin cells and in wild-type cells, motility of fluorescent phagosomes was directed from the oral cavity to the posterior end of the cell. Although 60% of fluorescent phagosomes in the MYO1-knockout strain were motile, movement of phagosomes was not directed toward the posterior end of the cell and was random. Forty percent of fluorescent phagosomes in knockout cells were non-motile in contrast to only 20% non-motile phagosomes in wild-type cells. The increased incidence of non-motile phagosomes in the knockout strain could reflect absence of Myo1p as a motor. Another myosin or other molecular motors could power random movement of phagosomes in the MYO1-knockout strain. In latrunculin-treated GFP-actin cells, movement of fluorescent phagosomes was random. Average velocity of random movement of fluorescent phagosomes in the knockout strain and in latrunculin-treated cells was statistically the same as the average velocity (2.0 +/- 1.9 microm/min) of phagosomes in GFP-actin cells. These findings are an indication that dynamic actin and Myo1p are required for directed motility of phagosomes.

Expression of GFP-actin leads to failure of nuclear elongation and cytokinesis in Tetrahymena thermophila.

Green fluorescent protein (GFP)-tagged actin was used to investigate the distribution and function of actin in Tetrahymena. A strain that expresses both GFP-actin and endogenous actin was developed by transformation of Tetrahymena thermophila with a ribosomal DNA-based replicative vector. Confocal microscopy of living cells and immunogold electron microscopy confirmed localization of GFP-actin to basal bodies and the contractile ring. Incorporation of the fusion protein into these and other actin-related structures correlated with severe impairment of macronuclear elongation and cytokinesis. At 30 degrees C macronuclear elongation failed to occur in 25% of the transformants despite completion of micronuclear division. At 20 degrees C macronuclear elongation failed to occur in 2% of the population. Arrest of cytokinesis coincided with failure of macronuclear elongation. Arrested cells developed into homopolar doublets with two sets of oral structures. This study indicates a requirement for actin in nuclear elongation and cytokinesis. Although GFP-actin can interfere with the functioning of actin-containing structures, the GFP-actin transformant strain can be used to monitor actin distribution and dynamics and is therefore an important new tool for further studies of Tetrahymena actin.