Histones,Chromatin Structure and RNA Synthesis

THE primary structure of the histone molecules is very irregular in the spacing of the basic amino-acids¹. In various histone fractions, there are some parts of the polypeptide chains with five basic amino-acids together and parts with up to fourteen non-basic amino-acids together^2,3. Nevertheless, this irregularity is extremely specific, for it has been shown for one of the arginine-rich histones that the amino-acid sequence has remained virtually unchanged since the divergence of plants and animals⁴. This indicates that this histone has an extremely important structural function in which the whole molecule is important. Although histones are known to be gene repressors, it is important to consider this role in relation to the other possibility that they are structural proteins.     

Induction of the Feline Oncornavirus Associated Cell Membrane Antigen in Human Cells

BY N-terminal amino-acid sequence analysis, Glenner et al.¹ have shown that amyloid fibrils are very similar to the variable part of an immunoglobulin kappa light chain (Bence-Jones protein Ker) and they suggested that amyloid is constituted by immunoglobulin light chains.     

Hypervariable Region of Human Immunoglobulin Heavy Chains

THE variable regions of human immunoglobulin light chains contain three areas of unusually high variability^1–4. Similar hypervariable regions have been postulated for human heavy chains^{5, 6}, but there are no amino-acid sequence data to support this idea. These hypervariable regions are particularly interesting because they may be the areas of the immunoglobulin molecule involved in antibody complementarity.We have made use of the recent observation that a variable region subclass of heavy chains is characterized by an unblocked amino-terminal residue⁷ and of the availability of automated sequencing techniques^{8, 9} to study this question in detail with additional heavy chain sequences.     

Amino-acid Sequence Homology in the Muscle Aldolases from Sturgeons of Different Species

STUDIES on the primary structure of aldolases isolated from ox, pig and rabbit muscle show that the amino-acid sequence of fructose 1,6-diphosphate aldolase [EC 4.1.2.13] has been highly conserved throughout mammalian evolution¹. But comparison of the primary structure of the enzyme from these species with that from the muscle of a single North Sea sturgeon, presumably Acipenser sturio, indicated that although the proteins were homologous, a number of amino-acid replacements occurred between sturgeon aldolase and the aldolases of the phylogenetically distant mammalian species¹. As a knowledge of the nature and number of amino-acid replacements between homologous proteins caft provide information both about the functional role of individual residues and about evolution, further comparative studies of rabbit and sturgeon aldolases were undertaken and an account of the sequence homology around the active-site-lysine residue of aldolases from rabbit muscle, rabbit liver and the muscle of the river sturgeon of Eastern Canada, Acipenser fulvescens, has been given^2,3.     

Complete amino-acid sequence and carbohydrate content of the naturally occurring glucosylceramide activator protein (A1 activator) absent from a new human Gaucher disease variant

Two naturally occurring non-enzymic glucosylceramide activator proteins (A1a and A1b activator) shown previously to be immunochemically not detectable in a new variant of human Gaucher disease (glucosylceramide lipidosis) without glucosylceramidase deficiency, were characterized by amino-acid sequence and carbohydrate content. The complete amino-acid sequence of the A1a activator was determined. The protein consists of 80 amino-acid residues including three disulfide bridges lacking arginine and tryptophan. The molecular mass is 8.95 kDa. About 20% of the polypeptide chain are shorter by two amino-acid residues at the N-terminal end. The A1b activator was characterized by the amino-acid compositions of all tryptic peptides and of the entire protein; sequencing was performed of the regions 1-34 and 42-56. Identical results were obtained for the polypeptide chains of both A1 activators. This suggests that they do not differ in their primary structures which is in agreement with the immunochemical results. The difference between A1a and A1b activator is due to the carbohydrate part. The total amount of 49% carbohydrate in A1a and 76.7% in A1b consists mainly of hexoses. Both chains contain two moles of N-acetylglucosamine per mole protein bound to asparagine in position 22. A comparison of the primary structure of the A1 activator with the sulfatide activator sequence revealed an interesting similarity, especially of the cysteine residues and the carbohydrate-binding asparagine. Sequence homology was also found between a part of the A1 activator sequence and the hemagglutinin neuraminidase of influenza virus as well as to a hypothetical glycoprotein of the Epstein-Barr virus. The comparison with human lysosomal glucosylcerebrosidase showed no sequence similarity.     

Polymorphic Alleles of the Gene for the β Chain of Rabbit Haemoglobin

THE primary structure of the haemoglobin chains from individuals of many species is not unique. The α chain of rabbit haemoglobin has six positions at which more than one amino-acid occurs¹. Such amino-acid multiplicities have also been found for the α chain of mouse^2,3, goat⁴ and horse⁵ haemoglobin and for the γ chain of human haemoglobin⁶. In some cases a simple mechanism can be put forward to explain the variability, as for the human γ chain⁶ and the mouse α chain³, where the presence of tandem genes seems to be established. Three of the variable positions of the α chain of rabbit haemoglobin can be explained as resulting from polymorphic alleles of a single α chain gene⁷.     

Amino-acid sensing and degrading pathways in immune regulation

Indoleamine 2,3-dioxygenases (IDOs) − belonging in the heme dioxygenase family and degrading tryptophan − are responsible for the de novo synthesis of nicotinamide adenine dinucleotide (NAD⁺). As such, they are expressed by a variety of invertebrate and vertebrate species. In mammals, IDO1 has remarkably evolved to expand its functions, so to become a prominent homeostatic regulator, capable of modulating infection and immunity in multiple ways, including local tryptophan deprivation, production of biologically active tryptophan catabolites, and non-enzymatic cell-signaling activity. Much like IDO1, arginase 1 (Arg1) is an immunoregulatory enzyme that catalyzes the degradation of arginine. Here, we discuss the possible role of amino-acid degradation as related to the evolution of the immune systems and how the functions of those enzymes are linked by an entwined pathway selected by phylogenesis to meet the newly arising needs imposed by an evolving environment.     

Synthesis of Haemoglobin Lepore

HAEMOGLOBIN Lepore is a class of haemoglobin variants composed of α-chains and hybrids of δ and β-chains, which can be designated as α₂(δβ)₂. The N-terminal amino-acid sequence of the hybrid chains corresponds to that of δ-chains, while the C-terminal sequence corresponds to that of β-chains. A misplaced synapse of the δ and β gene loci is thought to have occurred during meiosis, followed by a non-homologous cross-over¹. Three types are known which differ in the position of the cross-over: Hb Lepore Hollandia^2,3, Hb Lepore Baltimore⁴ and Hb Lepore Boston (Washington)^5,6.     

Isotypes in Human Immunoglobulin λ-Chains

IMMUNOGLOBULIN polypeptide chains consist of a variable N-terminal region and a constant C-terminal part¹. The variability of the N-terminal part is due to multiple amino-acid exchanges and deletions, which can be arranged into chemically distinct subgroups^2–9. The C-terminal part is characterized by single amino-acid substitutions in an otherwise constant, yet chain type specific, sequence^1,10–12.     

The primary structure of crystallizable monoclonal immunoglobulin IgG1 Kol. II. Amino acid sequence of the L-chain, gamma-type, subgroup I

The immunoglobulin Kol was the first intact antibody molecule which was characterized by high-resolution X-ray crystallography. Furthermore the complete amino-acid sequence of the heavy (H)-chain is known. Here we report the complete amino-acid sequence of the light (L)-chain of the monoclonal immunoglobulin Kol (IgG1). The polypeptide has an Mr of 22,781, consists of 216 amino acids and due to its structure is of the lambda-type. With the characteristic amino acids threonine, asparagine, threonine, glycine and lysine in positions 101, 114, 116, 154, and 165, respectively the Kol L-chain is of the Mcg isotype. With the proteins Mcg, Mot, Bur, Loc and Mem six myeloma-derived amino-acid sequences of the same isotype are known. The amino-acid sequence of the N-terminal variable part is characteristic of subgroup 1. This contribution completes the primary structure of IgG1 Kol.     

A comprehensive comparison of the metazoan tryptophan degrading enzymes

Tryptophan 2,3-dioxygenase (TDO) and indoleamine 2,3-dioxygenase (IDO) have an independent origin; however, they have distinctly evolved to catalyze the same reaction. In general, TDO is a single-copy gene in each metazoan species, and TDO enzymes demonstrate similar enzyme activity regardless of their biological origin. In contrast, multiple IDO paralogues are observed in many species, and they display various enzymatic properties. Similar to vertebrate IDO2, invertebrate IDOs generally show low affinity/catalytic efficiency for L-Trp. Meanwhile, two IDO isoforms from scallop (IDO-I and -III) and sponge IDOs show high L-Trp catalytic activity, which is comparable to vertebrate IDO1. Site-directed mutagenesis experiments have revealed that primarily two residues, Tyr located at the 2nd residue on the F-helix (F2^nd) and His located at the 9th residue on the G-helix (G9^th), are crucial for the high affinity/catalytic efficiency of these ‘high performance’ invertebrate IDOs. Conversely, those two amino acid substitutions (F2^nd/Tyr and G9^th/His) resulted in high affinity and catalytic activity in other molluscan ‘low performance’ IDOs. In human IDO1, G9^th is Ser¹⁶⁷, whereas the counterpart residue of G9^th in human TDO is His⁷⁶. Previous studies have shown that Ser¹⁶⁷ could not be substituted by His because the human IDO1 Ser¹⁶⁷His variant showed significantly low catalytic activity. However, this may be specific for human IDO1 because G9^th/His was demonstrated to be very effective in increasing the L-Trp affinity even in vertebrate IDOs. Therefore, these findings indicate that the active sites of TDO and IDO are more similar to each other than previously expected.     

Proton Magnetic Resonance Studies of Conformational Changes in Cleaved Halves of Histone F2B

THE amino-acid sequences of the histones F2A1¹ and F2B² are of particular interest in that they have such a high degree of non-uniformity that different regions of the polypeptide chains have quite different characters. The amino-halves of the molecules have a high density of basic residues while the carboxyl-halves have far fewer basic residues and higher proportions of apolar residues and other residues which favour the formation of helical conformations. These properties have led to the suggestions that the regions of high basicity are the primary sites for interaction with DNA^1–4 in chromatin and that the non-basic regions contain any secondary structure that the molecule is capable of forming^1–4 and are the sites for histone–histone interactions^3,4. Evidence in support of this scheme has been obtained from nuclear magnetic resonance and optical spectroscopic studies of conformational changes and interactions in histones F1 and F2A1³ and F2B⁴. In these studies, however, the whole molecule has been examined and the possibility of the formation of some secondary structure in the basic region of the molecule cannot be excluded.     

Interpretation of some Conformational Data in Myoglobin and Lysozyme

THE conformations of the polypeptide chains of myoglobin¹ and lysozyme² have been successfully simulated with the aid of computed Van der Waals contact and energy maps of the theoretical independent peptide unit (IPU)^3–5. The non-glycyl experimental points plotted on an alanyl IPU are rather scattered on the allowed conformational regions of the map⁶, especially in the case of lysozyme. By contrast, well defined clusters of points can be observed when only the amino-acid residues in segments of the helical secondary structure (mainly α and β chains) are plotted. In addition, clusters of points, albeit less well defined, can be observed by plotting the points relative to the experimental conformations of the first non-helical amino-acid residue next to a more or less folded segment of that α-helical type so frequently present in globular proteins (Fig. 1).     

Conservation among vertebrate immunoglobulin chains detected by antibodies to a synthetic joining segment peptide

We used affinity purified antibodies produced against a synthetic peptide sequence corresponding to the entire J beta of a human T cell receptor gene to screen sera of man, mouse and other vertebrates to determine the presence of cross-reactive molecules. Little evidence for free alpha/beta heterodimers was found, but the antibody reacted with light chains of many vertebrate species, including characterized myeloma proteins of man and mouse. Some vertebrate orders, notably Aves, lacked polypeptide chains cross-reactive with J beta, but detectable determinants occurred in primitive vertebrates such as the galapagos shark (Carcharhinus galapagensis). In addition to the strong cross-reaction with purified light chains, human heavy chains reacted weakly with the antibody. The cross-reaction correlated with the sequence of the denatured immunoglobulins and was inhibitable with free peptide. These results establish the similarity of T cell receptor beta chains to immunoglobulin chains and support the conclusion that J region sequences were conserved, not only within mammalian immunoglobulins and T cell receptors, but in vertebrate evolution.     

Translocation of non-interacting heteropolymer protein chains in terms of single helical propensity and size

In this work we present an analytical framework to calculate the average translocation time τ required for an ideal proteinogenic polypeptide chain to cross over a small pore on a membrane. Translocation is considered to proceed as a chain of non-interacting amino acid residues of sequence {X_j} diffuses through the pore against an energy barrier Δℱ, set by chain entropy and unfolding-folding energetics. We analyze the effect of sequence heterogeneity on the dynamics of translocation by means of helical propensity of amino acid residues. In our calculations we use sequences of fifteen well-known proteins that are translocated which span two orders of magnitude in size according to the number of residues N. Results show non-symmetric free energy barriers as a consequence of sequence heterogeneity, such asymmetry in energy may be useful in differentiated directions of translocation. For the fifteen polypeptide chains considered we found conditions when sequence heterogeneity has not a significant effect on the time scale of translocation leading to a scaling law τ ∝ N^ν, where ν ∼ 1.6 is an exponent that holds for most ground state energies. We also identify conditions when sequence heterogeneity has a great impact on the time scale of translocation, in consequence, no more scaling laws for τ there exist.     

Towards a chemical definition of idiotypy.

The idiotypic determinants have been precisely located to the variable regions of immunoglobulin polypeptide chains. Both chains are generally required to express the idiotype. The major idiotypic determinants are the result of the amino acid sequence of the hypervaiable regions, although some idiotypic determinants reside outside the antibody combining site and these so called "framework idiotypes" are important markers. In my view the hypervariable regions are spatially disposed so as to present adequate antigenic stimulation, and they display enough structural heterogeneity to account for the uniqueness of the idiotype in the general population of immunoglobulin molecules. Hypervariable regions, the antibody combining site, and the idiotypic determinants thus amalgamate three formerly diverse concepts into a unified theoretical construct.     

Alternate Positions for the Sulphydryl Group in β-Lactoglobulin: the Significance for Sulphydryl Location in Other Proteins

EARLIER studies of the location of the single cysteine residue and the two disulphide bridges in bovine β-lactoglobulins A and B¹, for each of which the monomer is a single chain of 162 residues and 18,000 molecular weight^2,3, led to the conclusion that the sulphydryl group is at position 69 and that the disulphides bridge positions 123 to 160 and 57 to 70. These results were based on diagonal peptide studies⁴ and on the composition of peptides in which the sulphydryl group had been labelled with ¹⁴C-iodoacetamide, the disulphide bridges being left intact. Use was made of the partial amino-acid sequence given by Frank and Braunitzer⁵ and the reasonable assumption was made that the sulphydryl occurred in only one position. Subsequently, Shaw⁶ has shown that the sequence of Frank and Braunitzer⁵ showing Cys residues adjacent at positions 69 and 70 is incorrect and that they are separated by a glutamine, the sequence for positions 67 to 71 for the Bvariant being Ala.Cys.Gln.Cys.Leu. Autoradiography of the dansyl amino-acid derivatives formed during the sequence determination of this pentapeptide indicated that both residues 68 and 70 seemed to have been labelled and so we have given further consideration to the sulphydryl location. It has been found that although it does occur at 68, with 57 and 70 disulphide bridged, there is also an equal amount of protein present with the sulphydryl at 70, with 57 and 68 disulphide bridged. We discuss this additional finding here and the significance for the determination of the location of sulphydryl groups in other proteins.     

Amino-acid Sequence of Human Placental Lactogen

AN earlier report from this laboratory¹ described striking homologies in the amino-acid composition of the peptides obtained from trypsin cleavage of human placental lactogen (HPL) and human growth hormone (HGH) and established a firm biochemical basis for the similarities in biological and immunological activity of the two hormones. The intrachain disulphide bonds were placed in similar locations and the carboxyl-terminal amino-acid sequences were shown to be identical except for one out of fourteen residues². In other studies^3,4, the amino-terminal sequence was determined and noted to be homologous for eleven of the first seventeen residues. We now report the complete amino-acid sequence of HPL and a comparison with the revised structure for HGH recently reported⁴. These two protein hormones are strikingly similar in structure, being identical in 85% of the corresponding positions. Of twenty-eight amino-acid substitutions, twenty-five are favoured changes and all but two of the twenty-five can be explained in terms of a single base change in the triplet codon⁵.     

Genetic Control of Variable and Constant Regions of Immunoglobulin Heavy Chains

IMMUNOGLOBULIN polypeptide chains consist of two well defined regions designated the “variable region” and the “constant region”. Whereas great diversity exists in amino-acid sequences of variable regions, the constant regions of a given subclass of heavy chains (C_H)^* are essentially invariant in sequence^{1, 2}. Exceptions are the allelic forms, such as the rabbit allotypes A14 and A15^{3, 4}, where a threonine-alanine interchange occurs in the constant region of γ chains (Appella, Chersi, R. G. M. and Dubiski, in preparation). The markers unique to a chains (for example, A14-A15) are closely linked to allotypic markers at the a locus (a1, a2, a3)^{3, 4} which seem to be present on four different Ig heavy chain classes (α, γ, ε, µ)^5–7. These puzzling observations can be explained if the a locus determinants are variable region markers which reflect genetically controlled differences in some relatively constant residues within the V_H region sequences⁷.     

Structure of the δ-Chain of Chimpanzee Haemoglobin A<Subscript>2</Subscript>

STUDIES of adult¹ and foetal² haemoglobin from the chimpanzee (Pan troglodytes) have shown that the amino-acid compositions of tryptic and chymotryptic peptides of the α, β and γ-chains are indistinguishable from those of man. The primary structures of chimpanzee α, β and γ-chains are therefore almost certainly identical to the homologous human chains. The two types of γ-chains found in man³, ^Gγ and ^Aγ, with glycine and alanine in position γ136, respectively, are likewise present in the chimpanzee².