Subunit structure and higher order assembly of the hemocyanins of the Melongenidae family: Melongena corona (Gmelin), Busycon canaliculatum (Linné), B. carica (Gmelin), B. contrarium (Conrad), and B. spiratum (Lamarck)

1. The hemocyanins of the Melongenidae family of marine gastropods: Melongena corona, Busycon canaliculatum, B. carica, B. contrarium, and B. spiratum exist in solution as multi-decameric aggregates characterized by sedimentation coefficients of approximately 105 S, 130 S, 150 S, 170 S, and higher values, corresponding to di-, tri-, tetra-, penta-, and larger multi-decameric particles. 2. The hemocyanins of B. contrarium and B. carica seem to form the largest decameric aggregates with the tri- to penta-decamers respresenting the major constitutents. Scanning transmission electron microscopy (STEM), both of unstained, freeze-dried and negatively-stained specimens, shows the presence of discrete aggregates consisting of up to ten decameric units. 3. The particle masses as determined by STEM mass measurements for individual molecules gave integral multiples of from 4.2 x 10(6) to 4.4 x 10(6) daltons ranging from about 8.2 x 10(6) daltons for the typical di-decamer of B. canaliculatum hemocyanin to as high as about 39 x 10(6) and 43 x 10(6) for the nano-and deca-decamers of B. contrarium hemocyanin. 4. The appearance of the higher multi-decamers in both negatively-stained and freeze-dried specimens suggest that they are formed by the addition of decameric units to a single di-decameric unit "tail-wise" in both directions. The higher aggregates formed seem to terminate with a closed head or collar at both ends of the assembly.     

Light-scattering and scanning transmission electron microscopic investigation of the hemocyanin of the bivalve, Yoldia limatula (Say)

1. The hemocyanin of the bivalve, Yoldia limatula (Say) was found by light-scattering to have a mol. wt of 8.0 +/- 0.6 x 10(6). Mass measurements by scanning transmission electron microscopy (STEM) gave a particle mass of 8.25 +/- 0.42 x 10(6) for the native particle and 4.09 +/- 0.20 x 10(6) for the half-molecule. 2. The hemocyanin subunits fully dissociated in 8.0 M urea and 6.0 M GdmCl at pH 8.0, and at pH 11.0, 0.01 M EDTA have mol. wts of 4.38 x 10(5), 4.22 x 10(5) and 4.71 x 10(5), close to one-twentieth of the parent molecular weight of Y. limatula hemocyanin and most gastropod hemocyanins. 3. Analyses of the urea dissociation transitions studied at pH 8.0, 1 x 10(-2) M Mg2+, 1 x 10(-2) M Ca2+ and pH 8.0, 3 x 10(-3) M Ca2+ suggest few hydrophobic amino acid groups, of the order of 10 to 15 at the contact areas of each half-molecule or decamer. 4. The further dissociation of the decamers to dimers and the dimers to monomers indicates the presence of a larger number of amino acid groups of ca 35-40/dimer and 100-120/monomer. 5. This suggests hydrophobic stabilization of the dimer to dimer and monomer to monomer contacts within the decamers, as observed with other molluscan hemocyanins.     

Subunit structure and higher order assembly of the hemocyanins of five members of the Naticidae family of marine gastropods: Calinaticina oldroydii (Dall), Euspira heros (Say), Neverita duplicata (Say), Polinices draconis (Dall), and Polinices lewisii (Gould)

1. The hemocyanins of the Naticidae family, E. heros, N. duplicata, P. draconis, P. lewisii and C. oldroydii were investigated by sedimentation velocity and scanning transmission electron microscopy. 2. At pH 8.0, 0.05 M Mg2+ E. heros hemocyanin is found to be predominantly in the tri-decameric state with a sedimentation coefficient (So20,w) of 131.3 (+/- 0.6) S. While the hemocyanin of N. duplicata is also mainly in the 130 S form, the hemocyanin of C. oldroydii is largely in the di-decameric form with a sedimentation coefficient close to 100 S. Other Naticidae hemocyanins, those of P. lewisii and P. draconis, have mixtures of the 100 S and 130 S di- and tri-decamers, and minor amounts of 150 S and faster sedimenting components. 3. The average particle masses based on STEM measurements are 8.85 x 10(6), 1303 x 10(6), and 17.1 x 10(6) da for the di-, tri-, and tetra-decameric assemblies of hemocyanin. 4. The subunit mol. wts of C. oldroydii hemocyanin and the published values for E. heros hemocyanin at alkaline pHs and in the presence of 8.0 M urea range from 4.2 x 10(5) to 4.8 x 10(5), suggesting the same decameric organization of the sub-assemblies of the Naticidae hemocyanins as for other molluscan hemocyanins. 5. The appearance of the larger hemocyanin particles in the electron micrographs support the hypothesis for their assembly that was based on similar studies of the hemocyanins of the Melongenidae family. According to this scheme the formation of higher aggregates is accomplished by the tail-to-head addition of each decameric unit to a central di-decamer which itself has the tail-to-tail Mellema and Klug arrangement of decamers. In this model all the higher aggregates terminate from either end with the same "collar" ends.     

Light-scattering investigation of the subunit structure and dissociation of Helix pomatia hemocyanin. Effects of salts and ureas

The effects of various salts of the Hofmeister and aliphatic acid salt series and hydrophobic reagents of the urea series on the subunit structure and the dissociation of Helix pomatia alpha-hemocyanin were investigated by employing light-scattering molecular weight methods. In moderate ranges of salt concentrations [0-1.0 M NaClO4, NaSCN, NaI, and guanidinium chloride (GdmCl) and 0-2.0 M NaBr], the dissociation reaction is essentially a two-step process characterized by the dissociation of whole hemocyanin molecules dissociating to half-molecules of decamers followed by the dissociation of the half-molecules to five dimeric fragments. The effectiveness of the salts and relative ineffectiveness of the ureas and GdmCl as dissociating agents in the first step of the dissociation reaction suggest that the stabilization of the contact areas between half-molecules in solution is largely a nonhydrophobic energy process involving polar and ionic interactions. Hydrophobic forces appear to be important, however, for stabilization of the half-molecules through side to side contacts of the five dimeric units that make up each half-molecule. The analysis of our dissociation data by use of equations derived in our previous studies [Herskovits, T. T., & Harrington, J.P. (1975) Biochemistry 14, 4964-4971] gave apparent estimates of amino acid groups of about 60-150 for each of the contact areas between the cylindrically shaped half-molecules and 30-60 for each of the dimers in the half-molecules themselves.(ABSTRACT TRUNCATED AT 250 WORDS)     

Big flies, small repeats: the "Thr-Gly" region of the period gene in Diptera

The region of the clock gene period (per) that encodes a repetitive tract of threonine-glycine (Thr-Gly) pairs has been compared between Dipteran species both within and outside the Drosophilidae. All the non- Drosophilidae sequences in this region are short and present a remarkably stable picture compared to the Drosophilidae, in which the region is much larger and extremely variable, both in size and composition. The accelerated evolution in the repetitive region of the Drosophilidae appears to be mainly due to an expansion of two ancestral repeats, one encoding a Thr-Gly dipeptide and the other a pentapeptide rich in serine, glycine, and asparagine or threonine. In some drosophilids the expansion involves a duplication of the pentapeptide sequence, but in Drosophila pseudoobscura both the dipeptide and the pentapeptide repeats are present in larger numbers. In the nondrosophilids, however, the pentapeptide sequence is represented by one copy and the dipeptide by two copies. These observations fulfill some of the predictions of recent theoretical models that have simulated the evolution of repetitive sequences.      

Evolutionary origin of human and primate malarias: evidence from the circumsporozoite protein gene

We have analyzed the conserved regions of the gene coding for the circumsporozoite protein (CSP) in 12 species of Plasmodium, the malaria parasite. The closest evolutionary relative of P. falciparum, the agent of malignant human malaria, is P. reichenowi, a chimpanzee parasite. This is consistent with the hypothesis that P. falciparum is an ancient human parasite, associated with humans since the divergence of the hominids from their closest hominoid relatives. Three other human Plasmodium species are each genetically indistinguishable from species parasitic to nonhuman primates; that is, for the DNA sequences included in our analysis, the differences between species are not greater than the differences between strains of the human species. The human P. malariae is indistinguishable from P. brasilianum, and P. vivax is indistinguishable from P. simium; P. brasilianum and P. simium are parasitic to New World monkeys. The human P. vivax-like is indistinguishable from P. simiovale, a parasite of Old World macaques. We conjecture that P. malariae, P. vivax, and P. vivax-like are evolutionarily recent human parasites, the first two at least acquired only within the last several thousand years, and perhaps within the last few hundred years, after the expansion of human populations in South America following the European colonizations. We estimate the rate of evolution of the conserved regions of the CSP gene as 2.46 x 10(-9) per site per year. The divergence between the P. falciparum and P. reichenowi lineages is accordingly dated 8.9 Myr ago. The divergence between the three lineages leading to the human parasites is very ancient, about 100 Myr old between P. malariae and P. vivax (and P. vivax-like) and about 165 Myr old between P. falciparum and the other two.      

Excitation of System I and System II in Photosynthesis as a Possible Control Mechanism of Glycolate Metabolism in the Blue-Green Alga Anacystis nidulans

Photosynthetic enhancement studies performed at 619 nm (excitation of Systems I and II) and at 446 nm (mainly excitation of System I) revealed an 18% photosynthetic enhancement simultaneously with a 31% reduction in glycolate excretion. This observation supports the hypothesis that some glycolate may be consumed in an oxidation process associated with System I when System II is poorly excited and the supply of electrons from the water splitting process of photosynthesis is low.     

Structural investigations on DNA-protamine complexes.

Protamine·DNA complexes in film and in solution have been investigated by means of infrared linear dichroism, ultraviolet circular dichroism, and laser Raman spectroscopy. At high relative humidity and in solution both infrared linear dichroism and ultraviolet circular dichroism indicate the presence of a modified B form of DNA (designated as B* in our other papers^27,28,46). This modified B form is characterized by a change of the orientation of the \documentclass{article}\pagestyle{empty}\begin{document}$ \widehat{OPO} $\end{document} bisector angle by about 4° with respect to the helical axis when compared to the B form of DNA. At decreasing relative humidities the same modified B form is maintained and no structural transitions B → A (or B → C) normally occurring in free DNA were observed. The absence of the A form in these complexes was also confirmed by laser Raman scattering studies of protamine·DNA complexes. On the basis of these results, a model of the protamine·DNA complex is proposed, which suggests that the presence of apolar amino-acid residues, and probably the folding of the polypeptide chain, is responsible for preventing the B-to-A transition; this occurs either by protecting the high-humidity modified B form against dehydration or by steric interference of this protein probably located in one of the DNA grooves.