Multiple genes provide the basis for antifreeze protein diversity and dosage in the ocean pout, Macrozoarces americanus

The ocean pout (Macrozoarces americanus) produces a set of antifreeze proteins that depresses the freezing point of its blood by binding to, and inhibiting the growth of, ice crystals. The amino acid sequences of all the major components of the ocean pout antifreeze proteins, including the immunologically distinct QAE component, have been derived by Edman degradation. In addition, sequences of several minor components were deduced from DNA sequencing of cDNA and genomic clones. Fifty percent of the amino acids are perfectly conserved in all these proteins as well as in two homologous sequences from the distantly related wolffish. Several of the conserved residues are threonines and asparagines, amino acids that have been implicated in ice binding in the structurally unrelated antifreeze protein of the righteye flounders. Aside from minor differences in post-translational modifications, heterogeneity in antifreeze protein components stems from amino acid differences encoded by multiple genes. Based on genomic Southern blots and library cloning statistics there are 150 copies of the 0.7-kilobase-long antifreeze protein gene in the Newfoundland ocean pout, the majority of which are closely linked but irregularly spaced. A more southerly population of ocean pout from New Brunswick in which the circulating antifreeze protein levels are considerably lower has approximately one-quater as many antifreeze protein genes. Thus, there appears to be a correlation between gene dosage and antifreeze protein levels, and hence the ability to survive in ice-laden seawater. Southern blot comparison of the two populations indicates that the differences in gene dosage were not generated by a simple set of deletions/duplications. They are more likely to be the result of differential amplification.     

DNA sequence organization in soybean investigated by electron microscopy

An electron microscopic analysis of the DNA sequence organization in the soybean genome is reported. This analysis employed the gene 32 proteinethidium bromide spreading technique, a procedure which produces striking contrast between double and single-stranded DNA regions. To investigate the arrangement of repetitive sequences differing in genomic frequency, three kinetic fractions of 5 kb DNA fragments were isolated by reassociation and hydroxyapatite chromatography. Renatured structures in each fraction were then visualized in the electron microscope. The majority of repeated sequences, irrespective of frequency, were shown to be relatively non-divergent, to exceed 1.5 kbp in length (number-average), and to be organized primarily into long regularly repeating tandem or clustered arrays. Duplex regions >5 kbp were commonly visualized. A small fraction of low frequency repeats (<100 copies per genome), however, was observed to have a distinctly different form of arrangement. These repeats averaged 0.2 kbp in length, contained divergent sequences, and were contiguous to single copy DNA sequences having an average length of 1.15 kbp. Repeats which flanked a given single copy sequence did not appear to be homologous. Neither short clustered permuted repeats nor interspersion of repeats which differed significantly in reiteration frequency were found to be major features of soybean genome organization.     

Inhibition of recrystallization in ice by chimeric proteins containing antifreeze domains

Using synthetic DNA, we assembled a gene encoding a protein identical in sequence to one of the antifreeze proteins produced by the fish Pseudopleuronectes americanus (winter flounder). To address the relationship between structure and function, we also assembled genes encoding proteins varying in sequence and length. The synthetic genes were cloned into a bacterial expression vector to generate translational fusions to the 3' end of a truncated staphylococcal protein A gene; the chimeric proteins encoded by these fusions, varying only in their antifreeze domains, were isolated from Escherichia coli. The antifreeze domains conferred the ability to inhibit ice recrystallization, which is characteristic of naturally occurring antifreeze proteins, on the chimeric proteins. The chimeric proteins varied in their effectiveness of inhibiting ice recrystallization according to the number of 11-amino acid repeats present in the antifreeze moiety. A protein with only two repeats lacked activity, while the inhibitory activity increased progressively for proteins containing three, four, and five repeats. Some activity was lost upon removal of either the salt bridge or the carboxyl-terminal arginine, but surprisingly, not when both features were absent together.     

Conserved sequences flank variable tandem repeats in two S-antigen genes of Plasmodium falciparum

We describe the isolation of two chromosomal DNA fragments from Plasmodium falciparum. These fragments encode the antigenically distinct S antigens of two different P. falciparum isolates, namely FC27 from Papua New Guinea and NF7 from Ghana. The complete nucleotide sequences of both fragments are presented. The fragments are homologous over most of their lengths, including the entire regions flanking the protein coding sequences. Whereas the N- and C-terminal portions of sequences encoding the S antigens are homologous, major portions of the coding sequences are not. The nonhomologous regions are comprised of tandemly repeated sequences, of 33 bp in FC27 and predominantly of 24 bp in NF7. The 33 bp tandem repeats encoded by the FC27 S-antigen gene could not be detected in the NF7 genome. Conversely, the 24 bp tandem repeats encoded by the NF7 S-antigen gene could not be detected in the FC27 genome. The pattern of sequence variation within the repeats of both genes suggests a mechanism for the generation of S-antigen diversity.     

Antifreeze protein pseudogenes.

Three members, 11-3, F2 and 5a, of the type-I antifreeze protein (AFP) multigene family in winter flounder were sequenced. All three belong to the subset of AFP genes that are linked, but irregularly spaced, and show significant differences from the functional genes in tandem repeats. 11-3 and F2 appear to be pseudogenes. Their intron, 3'-exon and 3'-flanking DNAs are similar to those of other AFP genes, but their 5'-exon is either missing or extensively modified, and has stop codons present in all three reading frames. Based on a comparison of intron sequences of family members, 11-3/F2 may represent a residual progenitor AFP gene which was duplicated after reaching pseudogene status. The third gene, 5a, is remarkable in having a 3'-exon that encodes an exceptionally long, Ala-rich sequence that lacks any semblance of the 11-amino acid repeats found in 11-3, F2 and functional AFP genes. 5a might also be a pseudogene, because its presumed TATA box appears to have mutated.     

Structural variations in the alanine-rich antifreeze proteins of the pleuronectinae

The sequence and activity of antifreeze proteins from two right eye flounder species were compared to assess the influence of structural variations on antifreeze capacity. The cDNA encoding the major serum antifreeze protein in the yellowtail flounder (Limanda ferruginea) was cloned from liver tissue. Its DNA sequence shows that the precursor to the antifreeze is a 97-residue preproportion. Edman degradation identified the N-terminus of the 48-amino-acid mature serum antifreeze protein and confirmed the sequence of the first 36 residues. A comparison with the previously determined winter flounder antifreeze protein and mRNA sequences shows strong homology through the 5' and 3' untranslated regions and in the peptide region. The mature protein section has the greatest sequence variation. Specifically, the yellowtail antifreeze protein, in contrast to that of the winter flounder, contains a fourth 11-amino-acid repeat and lacks several of the hydrophilic residues that have been postulated to aid in the binding of the protein to ice crystals. Intramolecular salt bridges are present in the antifreeze proteins from both species but in different registries with respect to the 11-amino-acid repeats. On a mass basis the yellowtail flounder antifreeze, though longer than that of the winter flounder, is only 80% as effective at depressing the freezing temperature of aqueous solutions. This lower activity might be due to the reduced number of hydrophilic ice-binding residues per molecule.     

Organization and primary nucleotide sequence of 5S rRNA genes in barley Hordeum vulgare

A BamHI DNA fragment of 301 bp corresponding to the main repeating unit of 5S rRNA was isolated from barley genomic DNA. The primary nucleotide sequence of this fragment was determined and a high level of homology was found between coding sequences of 5S rRNA genes of barley, wheat and rye. At the same time, spacer's nucleotide sequences of different species of cereals were changed dramatically. At least two types of 5S rRNA tandem repeats of 301 and 450 bp were found in barley genome. Polymorphism for restriction fragment length in 5S rRNA repeats allowed to discriminate between all barley varieties used in this work.     

Structure and evolution of the mammalian maltase-glucoamylase and sucrase-isomaltase genes

Maltase-glucoamylase and sucrase-isomaltase are two glycosydases responsible for starch digestion in human. Their evolutionary history was studied by comparing the amino acid sequences of these enzymes from several mammals and their orthologs from other chordates. The two glycosydases are paralogs and contain catalytic domains of the GH31 family. A common evolutionary precursor of their genes arose via a tandem duplication. As a consequence, sucrase-isomaltase consists of two homologous parts. The maltase-glucoamylase gene experienced several additional duplications, whose number varies among mammals. Its locus harbors four to seven tandem repeats, each coding for an amino acid sequence similar to the two parts of sucrase-isomaltase.     

Winter flounder antifreeze proteins: a multigene family

The nucleotide sequence of a cDNA clone of winter flounder antifreeze protein was determined by the dideoxynucleotide method. The sequence would predict a protein of 91 amino acids composed of a prepropeptide of 38 amino acids and a mature protein of 53 amino acids, which includes four complete 11-amino acid repeats. This predicted sequence corresponds to an antifreeze protein of intermediate size which is one 11-amino acid repeat longer than the smallest antifreeze proteins found in the serum of winter flounder during the cold season. Southern blot hybridization analysis of winter flounder genomic DNA with radioactive cDNA probes reveals a multigene family of potential antifreeze protein genes. This conclusion is supported by amino acid sequence analysis of several serum antifreeze proteins.     

Extrachromosomal DNA transformation of Caenorhabditis elegans.

DNA was introduced into the germ line of the nematode Caenorhabditis elegans by microinjection. Approximately 10% of the injected worms gave rise to transformed progeny. Upon injection, supercoiled molecules formed a high-molecular-weight array predominantly composed of tandem repeats of the injected sequence. Injected linear molecules formed both tandem and inverted repeats as if they had ligated to each other. No worm DNA sequences were required in the injected plasmid for the formation of these high-molecular-weight arrays. Surprisingly, these high-molecular-weight arrays were extrachromosomal and heritable. On average 50% of the progeny of a transformed hermaphrodite still carried the exogenous sequences. In situ hybridization experiments demonstrated that approximately half of the transformed animals carried foreign DNA in all of their cells; the remainder were mosaic animals in which some cells contained the exogenous sequences while others carried no detectable foreign DNA. The presence of mosaic and nonmosaic nematodes in transformed populations may permit detailed analysis of the expression and function of C. elegans genes.     

Structure and evolution of mammalian maltase-glucoamylase and sucrase-isomaltase genes

Maltase-glucoamylase and sucrase-isomaltase are two human glycosidases responsible for starch digestion. We have performed a comparative analysis of their amino acid sequences from several species of mammals and their orthologues from other chordates. This allowed us to determine the evolutionary history of the enzymes. Both glycosidases are paralogues and contain GH31 family catalytic domains. The common evolutionary precursor of these genes has arisen by a tandem duplication. As a consequence, sucrase-isomaltase consists of two homologous parts. The maltase-glucoamylase gene was a subject of several additional duplications, which number was not the same in different mammals. The locus, containing this gene, consists of 4-7 tandem repeats. The amino acid sequence, encoded by each of them, is similar to both parts of sucrase-isomaltase.     

The circumsporozoite gene of the Plasmodium cynomolgi complex

An analysis of the circumsporozoite (CS) genes of six closely related plasmodia is presented. Like other plasmodial antigens, the CS protein contains tandem repeats flanked by conventional nonrepeated sequences. Our analysis shows that the repeats, which encode the immunodominant epitope of the CS protein, diverge more rapidly than the remainder of the gene, and that the maintenance and evolution of the repeats cannot be explained as the result of selection at the protein level. We argue that a mechanism acts directly on the DNA sequence to constrain the internal divergence of the repeats, and as a result promotes their rapid divergence between taxa.     

Structures of two HaeIII-type genes in the human salivary proline-rich protein multigene family

Two members of the human salivary proline-rich protein (PRP) multigene family have been isolated and completely sequenced. These PRP genes, PRH1 and PRH2, are of the HaeIII-type subfamily and code for acidic PRP proteins. Both genes are approximately 3.5 kilobase pairs (kb) in length and contain four exons. Exon 3 encodes the proline-rich part of the protein and includes five 63-base pair (bp) repeats. CAT and ATA boxes and several possible enhancer sequences occur in a 1-kb region 5' to exon 1. Two sets of repeats occur in the sequenced region in addition to the 63-bp repeats: one pair of about 140 bp flanks 500 bp of DNA in the first intervening sequence, and the other pair of 72 bp is tandemly repeated 1.4 kb 5' to the PRH1 gene. The 4-kb region of sequenced DNA from PRH1 differs by an average of 8.7% from the same region in PRH2, but the nucleotide sequences of the exon 3 of the two genes differ by only 0.2%. This result suggests the occurrence of a recent gene conversion event. The regions containing the 5-fold repeated sequences of 63 bp are identical in the two genes, PRH1 and PRH2. A comparison of the human HaeIII and BstNI subfamily repeats and a comparison of the human, mouse, and rat repeats suggest that the individual repeats have evolved in a concerted fashion within each gene and within the PRP gene family as a whole.     

Ubiquitin genes as a paradigm of concerted evolution of tandem repeats

Summary Ubiquitin is remarkable for its ubiquitous distribution and its extreme protein sequence conservation. Ubiquitin genes comprise direct repeats of the ubiquitin coding unit with no spacers. The nucleotide sequences of several ubiquitin repeats from each of humans, chicken,Xenopus, Drosophila, barley, and yeast have recently been determined. By analysis of these data we show that ubiquitin is evolving more slowly than any other known protein, and that this (together with its gene organization) contributes to an ideal situation for the occurrence of concerted evolution of tandem repeats. By contrast, there is little evidence of between-cluster concerted evolution. We deduce that in ubiquitin genes, concerted evolution involves both unequal crossover and gene conversion, and that the average time since two repeated units within the polyubiquitin locus most recently shared a common ancestor is approximately 38 million years (Myr) in mammals, but perhaps only 11 Myr inDrosophila. The extreme conservatism of ubiquitin evolution also allows the inference that certain synonymous serine codons differing at the first two positions were probably mutated at single steps.