Assembly of fibrin. A light scattering study.

Using stopped flow light scattering, we show that assembly of fibrin following activation with non-rate-limiting amounts of thrombin or reptilase occurs in two steps, of which the first is end-to-end polymerization of fibrin monomers to protofibrils and the second is lateral association of protofibrils to fibers, in agreement with Ferry's original proposal. Polymerization is found to proceed as a bimolecular association of bifunctional monomers; the overall rate varies as the inverse first power of the concentration; end-to-end association of two monomers, of a monomer and an oligomer, and of two oligomers occurs with the same rate constant. The value of the rate constant is 8.2 C 10(5) M-1 s-1 in 0.5 M NaCl, is three times larger in 0.1 M NaCl (0.05 M Tris, pH 7.4), and is the same following activation by reptilase and by thrombin. The onset of growth of fibers from protofibrils takes 12 times longer in 0.5 than in 0.1 M salt, i.e. thick fibers ("coarse" gels) form from short protofibrils, and thin fibers ("fine" gels) form from longer protofibrils. Jumps of salt concentration at times when protofibrils, but not fibers, have formed result in immediate growth of thick fibers at low salt from long protofibrils formed at high salt. The rate of fiber growth in these experiments varies as the inverse first power of the concentration. 3the instant of gelation (formation of a network of fibers) falls in the later half of the time during which the scattering rises due to fiber growth; the rise of gel rigidity after gelation is found to continue beyond the end of this period. Jumps from low to high salt result in retention of whatever fibers have formed at low salt and a very small additional increase of the scattering due to further fiber growth at high salt. From a variety of evidence, we conclude that the properties of fibrin are determined by kinetics and not equilibria of assembly steps. Results obtained here agree with the following scheme of fibrin assembly: monomers polymerize to protofibrils; long protofibrils associate laterally to fibers; occasionally a long protofibril associates with two different fibers to form an interfiber connection; fiber growth does not reverse to yield stabler, more compact, structures and terminates in formation of a network of fibers. The typical delay of fiber growth is the time during which protofibrils form from monomers. Measurements at rate-limiting concentrations of thrombin have allowed estimation of turnover rates of fibrinopeptides that agree with kinetic parameters obtained with direct assay of fibrinopeptide. Release of fibrinopeptide B causes more rapid fiber formation. Addition of thrombin after activation by reptilase, at a time when protofibrils, but not fibers, have formed, is followed rapidly by fiber formation; this proves that thrombin readily removes fibrinopeptide B from protofibrils. On the basis of these new results and earlier work (in particular, Blomb?ck, B., Hessel, B., Hogg, D., and Therkildsen, L...     

Affinity of HMG17 for a mononucleosome is not influenced by the presence of ubiquitin-H2A semihistone but strongly depends on DNA fragment size.

We have used a two-dimensional (deoxyribonucleoprotein leads to DNA) electrophoretic binding assay to study the interaction of the purified high mobility group protein HMG17 with isolated HeLa mononucleosomes as a function of their DNA fragment size and the presence of ubiquitin-H2A semihistone. No significant differences between affinities of HMG17 for ubiquitinated and non-ubiquitinated core mononucleosomes were observed. In striking contrast, the apparent affinity of HMG17 for a mononucleosome increases more than 100-fold upon an increase of the length of the mononucleosomal DNA fragment by as few as 3 to 5 bp over the core DNA length (integral of 146 bp). We suggest that the magnitude of this effect is sufficient to explain the preferential binding of HMG17 in vitro to mononucleosomes derived from actively transcribed genes.     

Assembly analysis of ribosomes from a mutant lacking the assembly-initiator protein L24: lack of L24 induces temperature sensitivity

Summary Previously, we have shown that the ribosomal protein L24 is one of two assembly-initiator proteins. L24 is essential for early steps of the assembly of the 50S ribosomal subunit but it is not involved in both the late assembly and the ribosomal functions. Surprisingly, an E. coli mutant (TA109-130) exists which lacks L24. This apparent paradox is analyzed and resolved in this paper. The phenotypic features of the mutant lacking L24, are a temperature sensitivity (growth severely reduced beyond 34° C), a very low growth rate already at permissive temperatures (at least six-fold slower than wild type) and an underproduction of 50S subunits (molar ratio of 30S to 50S about 1:0.5). The S value of the mutant large subunits is 47S, and they are normally active in poly(Phe) synthesis. The total protein of the mutant large subunits show negligible activity in the total reconstitution assay using the standard two-step procedure. Number analysis of the assembly-initiator proteins revealed that only one initiator protein is effective, as expected. The activity is restored upon addition of wild-type L24. However, when the temperature of the first step is lowered from 44° to 36° C, reconstitution of active particles occurs with a 50% efficiency in the absence of L24. The recovery of activity is accompanied by the appearance of again two initiator proteins, when the mutant TP50 lacking L24 is used in the reconstitution assay at the permissive temperature of 36° C during the first step. These findings indicate that at least another protein or, alternatively, two other proteins take over the function of the assembly initiation at the lower temperature. Although the extent of the formation of active particles becomes independent of L24 below 36° C, the rate of formation is still strongly affected even at permissive temperatures. The presence of L24 reduces the activation energy of the rate-limiting step of the early assembly, i.e., the activation energy of RI ₅₀ ^* (1) formation is 43±4 kcal/mol in the presence and 83±9 kcal in the absence of L24. The results presented provide an explanation of the phenotypic features of the mutant solely due to the assembly effects caused by the lack of L24.     

Assembly of extracellular matrix.

A great challenge in understanding how different extracellular matrices assemble is to sort through the vast number of possible interactions between and among matrix molecules. The most profound insights are likely to come from patients with defined defects of matrix molecules and the use of transgenic mice or other experimental technologies that mimic the complexity of the human system.     

Assembly of bacteriophage T4 head-related structures. Assembly of polyheads in vitro.

The fine structure of Z-discs from frog, chameleon, rabbit, rat and human muscles was studied. Our data lead us to conclude that the basket-weave (woven) lattice represents the fundamental en face pattern of the vertebrate Z-disc, regardless of the manner of fixation, and we suggest that the large and small-“square” lattices are fixation artifacts. We also find that the woven lattice pattern remains essentially unchanged throughout physiological ranges of resting sarcomere length, and is not detectably altered by active contraction. A model of the vertebrate Z-line, based on anatomical and possible functional considerations, is presented. It presumes that a thin filament, as it enters the Z-line, is continuous with three curved strands which unite with other I-filaments of the same sarcomere. The I-filaments and extending strands from the opposite sarcomere are proposed to be similarly arranged, with the main Z-line substance consisting of the two sets of strands from adjacent sarcomeres. The anatomical features of the Z-line and the phenomenon of “Z-line splitting” are explained by the proposed model. In addition, a potential hexagonal structural arrangement of the Z-line is retained so that a consistent geometrical organization persists throughout the entire sarcomere. Thus, the model also presents a means of understanding the recently suggested role of the Z-line in forming new sarcomeres.     

Phosphorylation and acetylation of chromatin conjugate protein A24.

An analysis was made of the phosphorylation and acetylation of chromatin protein A24, a conjugate of histone 2A and ubiquitin. ³²P-orthophosphate was incorporated into phosphoserine of histone 2A and protein A24 in Novikoff hepatoma ascites cells in culture. The ratio of ³²P incorporation and the pattern of tryptic digestion of ³²P-labeled protein A24 indicated that the histone 2A component was phosphorylated and the ubiquitin component was not. Analysis of ε-N-acetyl lysine in protein A24, histone 2A and ubiquitin showed that while protein A24 and histone 2A were acetylated, ubiquitin was not. Apparently, even though it is conjugated with ubiquitin, the histone 2A portion of protein A24 has the same modifications as free histone 2A. The lack of modification of ubiquitin differs from that of high mobility group (HMG) non-histone chromatin proteins with which it is co-extracted from chromatin.     

Assembly of tobacco mosaic virus.

The assembly of tobacco mosaic virus requires the presence of a particular protein aggregate, the disk. During the nucleation, a specific region of the RNA interacts with a single disk, to bring about a necessarily cooperative transition from the paired two-layer structure to a short segment of nucleo-protein helix. There is a high selectivity for this region of the TMV RNA, because of the many nucleotides bound at once, and other nucleotide sequences appear only to bind by a different mechanism. Elongation of the nucleated rods can continue with either further disks or the less aggregated 'A-protein' as the protein source, but the continued cooperativity inherent with disks would have some advantages. The rates of the two processes have been separately determined and growth is faster when disks are still present. New experiments show that the breakdown of disks to yield A-protein is relatively slow and it is concluded that virus growth from disks could not proceed through a prior breakdown in solution, but must involve the direct interaction of the disk with the growing nucleoprotein rod. The detailed mechanism of disk addition is not understood but it may involve a directed breakdown, since there is also evidence for the existence of a non-equilibrium form of A-protein which has aggregation kinetics distinct from those of equilibrium A-protein. Some implications for the general assembly pathways of viruses both of the specificity and of the assembly/disassembly cycle during the viral infection are considered.     

Assembly of newly replicated chromatin.

Mild staphylococcal nuclease digestions under isotonic conditions release fragments of a 200 Å diameter fiber from nuclei of Drosophila melanogaster tissue culture cells. These soluble fragments have high sedimentation coefficients (30–100S) and show tightly packed nucleosomes in the electron microscope. Under the same conditions, newly replicated chromatin is released as more slowly sedimenting fragments (14S). Within 20 min after DNA replication, the nascent chromatin gradually matures into compact supranucleosomal structures which are indistinguishable from bulk chromatin on the isokinetic sucrose gradients.We have used this fractionation technique to examine the question of the fate and assembly of the new histones. After short pulses with either ³⁵S-methionine or ³H-lysine, the radioactive histones do not co-sediment with the bulk chromatin but appear instead in the fractions where the newly replicated DNA is found. Furthermore, the various nascent histones appear in different fractions on the gradient: histones H3 and H4 in 10–15S structures, histones H2A and H2B in 15–50S structures and histone H1 in 30–100S structures. These results, together with the analysis of pulse and pulse-chase experiments of both nascent DNA and histones, strongly suggest that histones H3 and H4 are deposited first on the nascent DNA (during or slightly after the DNA is replicated), histones H2A and H2B are deposited next (2–10 min later) and histone H1 is deposited last (10–20 min after DNA replication). A high turnover 20,000 dalton protein is also associated with the newly replicated chromatin.     

Rapid turnover of the histone-ubiquitin conjugate, protein A24.

The specific activity of protein A24 was found to exceed that of the core histones by 2-3 fold following a brief labeling period. Accordingly, the A24 protein was found to be unstable, with a decay half-life of 90 minutes. When decay of the ubiquitin moiety was measured, it was found to turn over more extensively than the H2A moiety.     

Assembly of hepatitis delta virus particles.

Hepatitis delta virus (HDV) is a subviral satellite of hepatitis B virus (HBV). Since the RNA genome of HDV can replicate in cultured cells in the absence of HBV, it has been suggested that the only helper function of HBV is to supply HBV coat proteins in the assembly process of HDV particles. To examine the factors involved in such virion assembly, we transiently cotransfected cells with various hepadnavirus constructs and cDNAs of HDV and analyzed the particles released into the medium. We report that the HDV genomic RNA and the delta antigen can be packaged by coat proteins of either HBV or the related hepadnavirus woodchuck hepatitis virus (WHV). Among the three co-carboxy-terminal coat proteins of WHV, the smallest form was sufficient to package the HDV genome; even in the absence of HDV RNA, the delta antigen could be packaged by this WHV coat protein. Also, of the two co-amino-terminal forms of the delta antigen, only the larger form was essential for packaging.     

Assembly of a spherical plant virus.

The conditions previously reported as necessary for the reassembly of spherical viruses have been distinctly unphysiological and such reassembly cannot be related directly to the in vivo reaction. Mild conditions for the in vitro reassembly of cowpea chlorotic mottle virus (CCMV) from its isolated components have now been described (Adolph & Butler 1975) and the reassembled virus characterized. This reassembly involved the co-aggregation of the RNA and protein around neutrality and at ionic strength 0.2, giving yields of 70% encapsidation at pH 6.0. The reaction was independent of temperature over the range 5-25 degrees C and did not require the presence of Mg2+ ions. The reassembled virus shows a stability similar to that of native CCMV, with the same change in sedimentation coefficient around pH 6.5. The molecular mass and buoyant density in CsCl are also the same as those of native CCMV, while the electron microscope reveals a surface morphology on the reassembled particles like that on native CCMV. Analysis of the number-average, mass-average, and Z-average molecular masses of the purified protein at both pH 6.0 and pH 7.5 suggests that the active unit for reassembly is a dimer of the protein subunit.