Structure-Function Relationships in Cellular Organelles Introductory Remarks by the Convener

Cells of the order Kinetoplastida possess a single mitochondrion which contains a large amount of a uniquely organized DNA. This kinetoplastic DNA (K-DNA), representing 10–20% of the total cell DNA in different species, has as its major molecular component a small closed circular molecule present in large numbers. The size and thereby the amount of genetic information carried by the minicircles varies from species to species: Leishmania tarentolae and the Salivarian trypanosomes have the smallest, the Stercorarian trypanosomes Trypanosoma lewisi and Trypanosoma cruzi intermediate, and Crithidia and also Trypanosoma mega the largest minicircles. In L. tarentolae, purified minicircles, which are the size of 1 gene, have been shown by renaturation kinetics to consist of only 1 or 2 classes. L. tarentolae K-DNA also contains another molecular species—a long molecule which may represent up to 30% of the total K-DNA. The minicircles, nevertheless, represent a gene amplification of the order of 10⁴. In all species that have been examined so far, the K-DNA consists of a single sheet of interlocked closed circular molecules which can be isolated in an intact form because of its resistance to shear forces and its high molecular weight. In addition, at least in L. tarentolae, 6–9% of the K-DNA is either free in the mitochondrion or loosely bound. The main K-DNA structure has been termed a “network” and can be seen in the light microscope after staining in solution with acridine orange or after fixing and staining with Giemsa's, or in the electron microscope. The quaternary structure of such networks in terms of the organization of minicircles and long molecules is not understood. Controlled breakdown of networks from L. tarentolae was achieved by sonication, and the release of open and closed monomeric minicircles, catenated dimers, trimers and higher oligomers, and short linear fragments was measured. A maximum of 43% of the total network DNA was released in the form of closed monomers, dimers, and trimers, thus providing a minimal estimate for the percentage of minicircles in K-DNA from this species. K-DNA replicates fairly synchronously with nuclear DNA in all species that have been examined. Replication of DNA molecules in the kinetoplast networks is limited to the periphery, as seen in autoradiographs of networks isolated from cells (L. tarentolae, Crithidia fasciculata) pulsed with ³H-thymidine. The molecular implications of this unusual replication pattern remain an open question, as does the genetic function of the K-DNA itself.     

Isolation and Characterization of Kinetoplast DNA Networks and Minicircles from Crithidia fasciculata*

SYNOPSIS. Covalently closed kinetoplast DNA networks have been isolated from stationary phase Crithidia fasciculata cells by a technic involving selective pelleting of the networks at a low centrifugal field. Approximately 62% of the kinetoplast DNA of the cell was recovered free of nuclear DNA by simple differential centrifugation. Purified kinetoplast DNA networks were visualized both in the electron microscope and in the light microscope. Closed networks sedimented as a homogeneous band both in neutral and alkaline sucrose, with an s_20w in neutral sucrose of approximately 5 × 10³. Closed monomeric minicircles were isolated from purified networks by mild sonication and band sedimentation in alkaline sucrose. Several physical properties of closed monomeric minicircles were measured. These included molecular weight, buoyant density in CsCl, superhelix density and sedimentation coefficient.     

Isolation and characterization of kinetoplast DNA and RNA of Phytomonas davidi

Kinetoplast DNA networks were isolated from stationary-phase culture forms of Phytomonas davidi. The networks banded in CsCl at a density of 1.699 g/ml and consisted of covalently closed circular molecules. The networks were sensitive to shear forces and exhibited several discrete sedimenting components in neutral and alkaline sucrose. Closed monomeric minicircles were isolated from sonicated networks by alkaline band sedimentation. Closed monomers showed a heterogeneous banding pattern on electrophoresis in acrylamide-agarose gels and had sedimentation coefficients of 20.5 S in alkaline sucrose and 11 S in neutral sucrose. The mean minicircle molecular weight as measured by cospreading with φXRF II was 0.70 × 10⁶ or 1064 nucleotide pairs. Minicircles exhibited a sequence microheterogeneity as evidenced by restriction enzyme analysis, melting analysis, and renaturation kinetics. Network maxicircles were evidenced by the appearance of high molecular weight fragments after restriction with several enzymes and by the existence of supertwisted “edge loops” extending out from the periphery of networks. The maxicircle molecular weight was estimated to be approximately 24 × 10⁶. A purified kinetoplast-mitochondrion fraction was found to contain 9 and 12 S RNA species that comigrated with L. tarentolae 9 and 12 S kinetoplast RNAs.     

Extra components in kinetoplast DNA preparations from Crithidiafasciculata

Kinetoplast DNA from the order Kinetoplastidae (trypanosomatids) exists as large associations (molecular weight 4 × 10¹⁰), made up of about 104 small, probably circular, molecules, commonly known as ‘minicircles’. These minicircles were originally thought to be identical in base composition, suggesting that the coding capacity of kinetoplast DNA is very restricted. However, linear molecules have also been observed in preparations of kinetoplast DNA, which, if they contain unique sequences, could represent additional genetic information. This linear DNA has been assumed to be derived from the kinetoplast, but the possibility of it being nuclear contamination has not been definitely ruled out. Work presented in this paper demonstrates that nuclear DNA contamination may indeed be present in kinetoplast DNA prepared by a commonly used method.     

Sedimentation studies of giant DNA molecules present in unsheared whole-cell lysates of D. melanogaster cells.

We have used band sedimentation in shallow density gradients of CsCl in the preparative centrifuge to analyze the distribution of sedimentation coefficients present in tritium labelled DNA from D. melanogaster cells. The cells were lysed according to the method of Kavenoff and Zimm to preserve very high molecular weight DNA. Sedimentation measurements have been carried out as a function of speed of centrifugation. The resulting distribution functions have been interpreted with the aid of the Zimm-Schumaker equation for the speed dependence of the sedimentation coefficient of very high molecular weight DNA. Low-speed centrifugation (3000 rpm) indicates that DNA molecules from the lysate are evenly distributed over values of S_20,w from 0 to 514S. This distribution is very sensitive to changes in speed of centrifugation and is transformed into a bimodal distribution at 12,080 rpm. Analysis of this transformation allows us to postulate that perhaps 55% of the DNA in the lysate may have molecular weights in excess of 40 × 10⁹ g/mol. Some of these molecules may also possess a variety of configurations including partially replicated branched structures.     

A nicking enzyme from trypanosomatids which specifically affects the topological linking of duplex DNA circles. Purification and characterization

Newly replicated duplex DNA minicircles of trypanosomal kinetoplast DNA are nicked in both their monomeric and catenated topological states, whereas mature ones are covalently sealed. The possibility that nicking may play a role during kinetoplast DNA replication by affecting the topological interconversions of monomeric DNA minicircles and catenane networks was studied here in vitro using Crithidia fasciculata DNA topoisomerase. An enzyme that catalyzes the nicking of duplex DNA circles has been purified to apparent homogeneity from C. fasciculata cell extracts. The native enzyme has a sedimentation coefficient of 6.8 S and was found to be a dimer with a protomer Mr = 60,000. Nicking of kinetoplast DNA networks by the purified enzyme inhibits their decatenation by the Crithidia DNA topoisomerase but has no effect on the catenation of monomeric DNA minicircles into networks. This differential effect on decatenation versus catenation is specific to the purified nicking enzyme. Random nicking of interlocked DNA minicircles has no detectable effect on the reversibility of the topological reaction. The potential role of Crithidia nicking enzyme in the replication of kinetoplast DNA networks in trypanosomatids is discussed.     

Mitochondrial minicircles in the free-living bodonid Bodo saltans contain two gRNA gene cassettes and are not found in large networks

In trypanosomatids, the majority of the guide (g) RNAs that provide the information for U-insertion/deletion RNA editing are encoded by minicircles that are catenated into large networks. In contrast, in the distantly related cryptobiid Trypanoplasma borreli, gRNA genes appear to reside in large 180-kb noncatenated DNA circles. To shed light on the evolutionary history and function of the minicircle network, we have analyzed minicircle organization in the free-living bodonid Bodo saltans, which is more closely related to trypanosomatids than T. borreli. We identified 1.4-kb circular DNAs as the B. saltans equivalent of minicircles via sequence analysis of 4 complete minicircles, 14 minicircle fragments, and 14 gRNAs. We show that each minicircle harbors two gRNA gene cassettes of opposite polarity residing in variable regions of about 200 nt in otherwise highly conserved molecules. In the conserved region, B. saltans minicircles contain a putative bent helix sequence and a degenerate dodecamer motif (CSB-3). Electron microscopy, sedimentation, and gel electrophoresis analyses showed no evidence for the existence of large minicircle networks in B. saltans, the large majority of the minicircles being present as circular and linear monomers (85-90%) with small amounts of catenated dimers and trimers. Our results provide the first example of a kinetoplastid species with noncatenated, gRNA gene-containing minicircles, which implies that the creation of minicircles and minicircle networks are separate evolutionary events.     

The influence of rotor speed on the sedimentation behavior in sucrose gradients of high molecular weight DNA's

Anomalous sedimentation behavior has been observed for high molecular weight duplex DNA's in sucrose gradients. The sedimentation rate of DNA's having molecular weights of 10⁸ or higher is influenced by high centrifugal fields. The change in the sucrose sedimentation coefficient due to this effect, S^RPM_suc-S⁰_suc, is equal to 1 × 10^?48M^3.65( The anomalous behavior is not influenced by DNA concentration at sufficiently low concentrations. Because of the smallness of the coefficient this effect has not been previously detected for DNA's the size of T2 or smaller at rotor speeds below 40000 RPM. For example, the relative sedimentation coefficient of T2 DNA at 65 000 RPM is only 9% less than at 10000 RPM. However, the sedimentation profile of heterogeneous high molecular weight [(100 – 350) × 10⁶] E. coli DNA is severely altered even at moderate rotor speeds (37000 RPM). Therefore, it seems advisable to use low rotor speeds when sedimenting high molecular weight DNA's.     

Intracellular events during infection by Haemophilus influenzae phage and transfection by its DNA

Intracellular events following infection of competent Haemophilus influenzae by HPlcl phage, or transfection by DNA from the phage, were examined. Physical separation of a large fraction of the intracellular phage DNA from the bulk of the host DNA was achieved by lysis of infected or transfected cells with digitonin, followed by low-speed centrifugation. The small amount of bacterial DNA remaining with the phage DNA in the supernatants could be distinguished from phage DNA by its ability to yield transformants. After infection by whole phage, three forms of intracellular phage DNA were observable by sedimentation velocity analysis: form III, the slowest-sedimenting one; form II, which sedimented 1.1 times faster than III, and form I, which sedimented 1.6 times faster than III. It was shown by electron microscopy, velocity sedimentation in alkali, and equilibrium sedimentation with ethidium bromide, that forms I, II and III are twisted circles, open circles, and linear duplexes, respectively.After the entry of phage DNA into wild-type cells in transfection, the DNA is degraded at early times, but later some of the fragments are reassembled, resulting in molecules that sediment faster than the monomer length of phage DNA. Some of the fast-sedimenting molecules are presumably concatemers and are generated by recombination. In strain rec₁^? the fast-sedimenting molecules do not appear and degradation of phage DNA is even more pronounced than in wild-type cells. In strain rec₂^? there is little degradation of phage DNA, and the proportion of fast-sedimenting molecules is much smaller than in wild-type cells. Since rec₁^? and rec₂^? are transfected with much lower efficiency than wild type, our hypothesis is that both fragmentation and generation of fast-sedimenting phage DNA by recombination are required for more efficient transfection.     

Sedimentation Rate as a Measure of Molecular Weight of DNA

Zone centrifugation of mixtures of two labeled DNA's at low concentrations in density gradients of sucrose permits accurate measurement of relative sedimentation rates. The individual rates are constant during the run. Measurements with DNA's from phages T2, T5, and lambda conform to the relation D₂/D₁ = (M₂/M₁)^0.35, where D and M refer to distances sedimented and molecular weights of the DNA pair. The results show that high molecular weight DNA's sediment artificially fast in the optical centrifuge, owing to a hitherto unknown effect of molecular interactions. The molecular weight of lambda DNA is 31 million, measured either from sedimentation rate or from tests of fragility under shear.     

THE FORM AND STRUCTURE OF KINETOPLAST DNA OF CRITHIDIA

Cesium chloride centrifugation of each of the DNAs extracted from eight strains of Crithidia revealed a main band at ρ = 1.717 g/cm³ and a satellite band varying from ρ = 1.701 to 1.705 g/cm³ for the different strains By electron microscopy each DNA was shown to include circular molecules, 0.69–0.80 µ in mean contour length, and large, topologically two-dimensional masses of DNA in which the molecules appeared in the form of rosettes. DNA isolated from kinetoplast fractions of Crithidia acanthocephali was shown to consist of light satellite DNA and to be mainly in the form of large masses, 0.8 µ (mol wt = 1.54 x 10⁶ daltons) circular molecules, and a few long, linear molecules. The results of experiments involving ultracentrifugation, heating, and quenching, sonication, and endodeoxyribonuclease digestion, combined with electron microscopy, are consistent with the following hypothesis. The large DNA masses are associations of 0.8 µ circles which are mainly covalently closed. The circles are held together in groups (the rosettes) of up to 46 by the topological interlocking of each circle with many other circles in the group. A group of circles is attached to an adjacent group by one or more circles, each interlocking with many circles of both groups. Each of the associations comprises, on the average, about 27,000 circles (total mol wt 41 x 10⁹ daltons). A model is proposed for the in situ arrangement of the associations which takes into consideration their form and structure, and appearance in thin sections     

Sedimentation velocity properties of catenated DNA molecules from HeLa cell mitochondria

Catenated molecules of closed circular DNA have been isolated from the mitochondrial DNA of HeLs cells. The sedimentation coefficients of several purified species have been investigated. The catenated dimer, made up of two interlocked duplex circles, sediments at 51 S in its superhelical (closed) form. Treatment with pancreatic DNase to relax the duplex circles converts the 51 S doubly closed dimer to a 42 S singly open species, then to a 36 S doubly open catenated dimer. The triply closed trimer sediments at 63 S and is converted to a 45 S triply open form by DNase. Electron microscopy of the DNA samples before and after DNase treatment shows that under the conditions used DNase does not change the catenated nature of the DNA. The measured sedimentation coefficients, have been compared with those estimated from previously proposed correlations of sedimentation coefficient and molecular weight, and with the sedimentation coefficients for catenated DNA presented by Wang. When all the interlocked circles in a catenane are relaxed, the DNA sediments about 5–10% faster than a relaxed multiple-length circular molecule of the same molecular weight. The sedimentation coefficient, 36 S, of the fully relaxed catenated dimer is 1.4 times that of the relaxed monomer.     

Isolation of the Kinetoplast DNA of Leishmania tarentolae in the Form of a Network*

The major kinetoplast DNA complement of Leishmania tarentolae promastigotes has been isolated as a single sheet of interconnected molecules on the basis of its relative stability to shear forces and its high sedimentation coefficient. Two successive differential centrifugations were sufficient to recover 50 ± 10% of the total kinetoplast DNA free of nuclear DNA contamination. We use the term “network” to describe this unusual type of DNA configuration. Leishmania networks have a molecular weight of ～10¹⁰ daltons and an S_20,W in neutral sucrose gradients of 1729 7plusmn; 189 [n = 19] and exhibit an extremely low specific viscosity due to the compactness of packing of the DNA. The networks were visualized in the electron microscope, and in the light microscope either by fluorescence in solution after staining with acridine orange or in dried smears after staining with Giemsa. Purified networks from stationary phase cells banded in the position characteristic of closed monomeric minicircles in ethidum bromide-CsCl equilibrium gradients, and were stable in alkaline sucrose. Treatment of the closed networks with RNase and pronase had no effect on the ethidium bromide-CsCl banding pattern. However, treatment of closed networks with DNase I or II, X-irradiation or γ-irradiation changed the banding pattern by introducing single strand and double strand breaks, yielding an upper band and in some cases a intermediate band.     

Organized packaging of kinetoplast DNA networks

The kinetoplast DNA (kDNA) of Trypanosoma equiperdum is organized as a complex structure of catenated circular DNA molecules. The major component of the kDNA network is the one kilobase minicircle that is present at about 10,000 copies per network. We have developed two assays to examine the structure of kDNA networks compacted in vitro with spermidine. Our results suggest that minicircles are arranged into a regular structure with an exposed domain which is DNAase I- and restriction-sensitive and a protected domain which is resistant to restriction endonucleases and DNAase I. This regularly packaged structure is dependent upon spermidine compaction and the circularity of the kDNA, but does not require supercoiled minicircles or catenated networks.     

Pankinetoplast DNA structure in a primitive bodonid flagellate, Cryptobia helicis.

The mitochondrial DNA (mtDNA) of a primitive kinetoplastid flagellate Cryptobia helicis is composed of 4.2 kb minicircles and 43 kb maxicircles. 85% and 6% of the minicircles are in the form of supercoiled (SC) and relaxed (OC) monomers, respectively. The remaining minicircles (9%) constitute catenated oligomers composed of both the SC and OC molecules. Minicircles contain bent helix and sequences homologous to the minicircle conserved sequence blocks. Maxicircles encode typical mitochondrial genes and are not catenated. The mtDNA, which we describe with the term 'pankinetoplast DNA', is spread throughout the mitochondrial lumen, where it is associated with multiple electron-lucent loci. There are approximately 8400 minicircles per pankinetoplast-mitochondrion, with the pan-kDNA representing approximately 36% of the total cellular DNA. Based on the similarity of the C.helicis minicircles to plasmids, we present a theory on the formation of the kDNA network.     

Characterization of the Bacillus subtilis W23 genome by sedimentation

Sedimentation measurements of DNA gently extracted from stationary-phase cells of Bacillus subtilis demonstrated molecules large enough to account for the total genome. The observed sedimentation coefficient of the putative genome showed a strong dependence on centrifuge speed and was, therefore, measured at very low speeds. The value for the sedimentation coefficient extrapolated to zero speed was 159 ± 19 s, from which was calculated molecular weights of (2.5 ± ^1.2_0.8) × 10⁹ a.m.u. for linear molecules and (1.8±^0.8_0.7) × 10⁹ a.m.u. for circular molecules (relative to the following values for T2 DNA: 57 s and 132±12 × 10 daltons; Leighton &; Rubenstein, 1969). The genome also showed extreme shear sensitivity.     

Minicircle variation in Beta mitochondrial DNA

Summary Mitochondrial DNAs from nine male fertile and eight cytoplasmic male sterile (cms) accessions of wild and cultivated Beta beets were investigated for the presence of low molecular weight DNA molecules. Five different supercoiled DNA molecules were detected, varying in size from 1.33 to 1.63 kb. Southern hybridizations revealed multimeric forms and sequence homologies between the minicircles. The occurrence of the different minicircles among the 17 accessions was investigated by agarose gel electrophoresis and Southern hybridization using minicircle specific probes. The 1.33 and 1.63 kb minicircles were found in most accessions, the other three minicircles were found in one or two of the wild Beta beet accessions. The presence of a low number of small, more or less homologous, minicircles in all investigated plants makes these molecules a general characteristic of Beta mtDNA. No association is found between the presence or absence of specific minicircles and the expression of male sterility. Neither does the distribution of the different minicircles in Beta beets indicate any essential biological role of these minicircles.     

Anomalies in sedimentation. IV. Decrease in sedimentation coefficients of chains at high fields

A theory is presented for the decrease of sedimentation coefficient at high centrifugal fields recently reported for samples of DNA by Rubenstein and Leighton and others. The theory uses the model of a chain of beads and springs to represent the molecule. Kirkwood's approximation is used for the sedimentation coefficient. The decrease in sedimentation coefficient with field comes about as a result of the uneven frictional forces in the chain, which on the average are less on segments near the center of the chain than on those near the ends. As a result the ends of the chain tend to drag behind the center, and the average intersegment distances are increased; consequently the hydrodynamic shielding of one segment by another is reduced, and the average friction is increased. The effect is thus characteristic of single molecules; intermolecular interaction is not involved. The sedimentation coefficient, S, varies as a power series in a parameter y that measures the distortion produced by the uneven friction: S = S⁰(1?D₂y² + D₄y⁴ ? ·). where S⁰ is the limiting value of S at zero centrifugal field and D₂ and D₄ are constants; y is proportional to the cen speed squared tunes the molecular weight squared divided by S⁰. It has been observed that the effects of centrifuge speed on S are negligible below certain critical values of the speed and molecular weight, but increase dramatically immediately above these values; this follows naturally from the high powers of the speed and molecular weight that appear in the above equation.     

The segregation of kinetoplast DNA networks in Trypanosoma brucei

The kinetoplast DNA of Trypanosoma brucei consists of 10⁴ minicircles (0.3 μm) and 10² maxicircles (6 μm) held together by catenation in a complex network. In electron micrographs of kinetoplast DNA spread in a protein monolayer we have identified four types of network with the appearance of different stages in network replication and segregation. We show that each network type has characteristic properties with respect to shape, size, number, and location of maxicircle loops and nicked or covalently closed character of minicircles and maxicircles. We propose a detailed model for network segregation that involves a gradual elongation of the network, followed by network cleavage. During this process the basic network structure remains unaltered, implying a complicated mechanism of minicircle rearrangements.