Cloning of the genomic sequence encoding a processed adenylate kinase 2 pseudogene

A chromosomal DNA sequence harboring a processed AK2B pseudogene was isolated from a human genomic library. It was a variant of the AK2B gene sequence including several point mutations, deletions, and insertions. The nucleotide sequence of the ORF of the AK2B pseudogene predicted a truncated form of the AK2B mutant suggesting that the processed pseudogene is nonfunctional. A repetitive sequence, AAAAGAGAG, found in the 5' and 3' flanking regions of the pseudogene and the poly(A) tract in the 3' end junction suggest that a mRNA of AK2B may have been converted to the processed pseudogene by retrotransposition events. Previously, it was suggested that an adenylate kinase (AK) 2 related gene on chromosome 2, confirmed by Southern analysis using somatic cell hybrid cell lines, may be a processed pseudogene. It is proposed that the processed pseudogene isolated in this study may be the AK2 related nonfunctional gene localized on human chromosomes 2.     

Inactivation of human keratin genes: the spectrum of mutations in the sequence of an acidic keratin pseudogene

Keratins are cytoskeletal proteins encoded by a multigene family. We have identified the first human keratin pseudogene and determined its complete nucleotide sequence. Sequence comparisons indicate that the pseudogene arose from a very recent duplication of the 50-kd keratin (K14) gene. The coding and the intron sequences of the two genes are 95% and 93% identical, respectively. Although the sequence of the regulatory region in the pseudogene is virtually identical to that in the 50-kd functional gene, several deleterious mutations have been identified in the pseudogene. There are three frameshifts in the coding regions, one of which is a perfect 8-bp duplication. A single-base-pair deletion in the first exon and a single-base-pair insertion in the penultimate exon also result in frameshifts. The three remaining deleterious mutations interfere with the mRNA processing signals: two alter the intron/exon boundaries, and the third disrupts the polyadenylation signal. These mutations clearly identify the sequence as a human keratin pseudogene.     

Genomic analysis of the 67-kDa laminin receptor in normal and pathological tissues: circumstantial evidence for retroposon features.

We have cloned two cDNAs for the human 67-kDa laminin receptor (LR). In the present report we show that these clones hybridize to many restriction fragments in Southern experiments in human. This particular pattern is accounted for by the presence of up to 16 and 21 copies of the laminin receptor gene per haploid genome in human and mouse, respectively. In contrast, a single gene copy is found in chicken. Chromosomal localization reveals four main loci: LAMRP1, laminin receptor pseudogene 1 (Chr 3); LAMRP2, laminin receptor pseudogene 2 (Chr 12); LAMRP3, laminin receptor pseudogene 3 (Chr 14); LAMRP4, laminin receptor pseudogene 4 (Chr X). Comparison of our experimental results to the known features of processed retropseudogenes enabled us to conclude that the LR gene belongs to a retroposon family in mammals.     

Proteinases encapsulated in stimulated release liposomes for cheese ripening

Chymosin, a neutral proteinase from Bacillus subtilis and cardoon cyprosins, were co-encapsulated with phospholipase C in stimulated release liposomes. Encapsulated enzymes were added separately to milk to make cheese. Chymosin and the neutral proteinase accelerated as-casein degradation in comparison with control cheese, whereas b-casein degradation was accelerated by neutral proteinase and cyprosins. Neutral proteinase yielded the highest increase in soluble nitrogen. Cheese flavour intensity was enhanced by the neutral proteinase and cyprosins but not by chymosin.     

Opal suppressor phosphoserine tRNA gene and pseudogene are located on human chromosomes 19 and 22, respectively

An opal suppressor phosphoserine tRNA gene and pseudogene have been isolated from a human DNA library and sequenced (O'Neill, V., Eden, F., Pratt, K., and Hatfield, D. (1985) J. Biol. Chem. 260, 2501-2508). Southern hybridization of human genomic DNA with an opal suppressor tRNA probe suggested that the gene and pseudogene are present in single copy. In this study, we have determined the chromosome location of the human gene and pseudogene by utilizing a 193-base pair fragment encoding the opal suppressor phosphoserine tRNA gene as probe to examine DNAs isolated from human-rodent somatic cell hybrids that have segregated human chromosomes. These studies show that the probe hybridized with two regions in the human genome; one is located on chromosome 19 and the second on chromosome 22. By comparing the restriction sites within these two regions to those previously determined for the human opal suppressor phosphoserine tRNA gene and pseudogene, we tentatively assigned the gene to chromosome 19 and the pseudogene to chromosome 22. These assignments were confirmed by utilizing a 350-base pair fragment which was isolated from the 5'-flanking region of the human gene as probe. This fragment hybridized only to chromosome 19, demonstrating unequivocally that the opal suppressor phosphoserine tRNA gene is located on chromosome 19. The flanking probe hybridized to a single homologous band in hamster and in mouse DNA to which the gene probe also hybridized, demonstrating that the 5'-flanking region of the opal suppressor tRNA gene is conserved in mammals. Restriction analysis of DNAs obtained from the white blood cells of 10 separate individuals demonstrates that the gene is polymorphic. This study provides two additional markers for the human genome and constitutes only the second set of two tRNA genes assigned to human chromosomes.     

Ribonuclease H1 maps to chromosome 2 and has at least three pseudogene loci in the human genome

We have analyzed the genomic structure of ribonuclease H1 (RNase H1) loci in the human genome. Human PAC library screening combined with database searches indicated that several loci are present. The transcribed gene is localized on chromosome 2p25. This was confirmed by RNA analysis of a monochromosomal hybrid cell line that expressed human chromosome 2. These data contradict a previous report, as well as the current Human Genome Project (HGP) annotation, which had placed the gene on chromosome 17p11.2. This location represents a pseudogene. Another highly similar pseudogene is present at a separate locus located more distal on chromosome 17p, while a third pseudogene is localized on chromosome 1q.     

Chromosomal localization and racial distribution of the polymorphic human dihydrofolate reductase pseudogene (DHFRP1).

The human dihydrofolate reductase (DHFR) gene family comprises one functional gene and at least four intronless processed pseudogenes. The functional DHFR gene is on chromosome 5, and DHFRP4 is on chromosome 3. Using in situ hybridization, we have now localized the functional DHFR gene to the region q11.1-q13.3 on chromosome 5. By genomic DNA analysis of a panel of human X rodent somatic-cell hybrids, we determined the chromosomal assignment of the DHFRP1 pseudogene to chromosome 18 and that of the DHFRP2 pseudogene to chromosome 6. The DHFRP1 pseudogene exhibits a novel form of polymorphism in humans in that it is present in the DNA of some individuals and absent in that of others. We investigated the racial distribution of this pseudogene in five racial groups. The allelic frequency as defined by analysis of 180 chromosomes was found to be 94% in Mediterraneans, 77% in Asian Indians, 67% in Chinese, 57% in Southeast Asians, and 32% in American blacks. These data suggest that the transposition of this "perfect" pseudogene occurred prior to the inception of the human racial groups.     

The primate psi beta 1 gene. An ancient beta-globin pseudogene

The human beta-globin gene cluster contains five functional genes plus a single pseudogene termed psi beta 1. Hybridization and comparative sequence analysis show that this pseudogene is not the product of a recent gene duplication, but is ancient and has been maintained in all major primate groups ranging from prosimians to anthropoids, at the same position as in man, between gamma- and delta-globin genes. In the lemur, a prosimian, the central exons of the psi beta 1 and delta-globin genes have undergone an unequal exchange, which has resulted in a contraction of the beta-globin gene cluster and the formation of a Lepore-type psi beta 1-delta globin pseudogene. Comparisons of defects shared by prosimian, New World monkey and human psi beta 1 sequences suggest that the ancestral primate gene was probably a pseudogene with an abnormal initiation codon but few if any additional defects, and that most contemporary pseudogene defects were accumulated relatively recently by slow neutral drift. We suggest that psi beta 1 arose early in primate evolution by silencing of a pre-existing discrete functional gene, and show that psi beta 1-related sequences are also present in other mammalian orders. In view of the antiquity of psi beta 1-related sequences, we propose that this gene be renamed the eta-globin gene.     

Eleven daughters of NANOG

Nanog is a recently discovered ANTP class homeobox gene. Mouse Nanog is expressed in the inner cell mass and in embryonic stem cells and has roles in self-renewal and maintenance of pluripotency. Here we describe the location, genomic organization, and relative ages of all human NANOG pseudogenes, comprising ten processed pseudogenes and one tandem duplicate. These are compared to the original, intact human NANOG gene. Eleven is an unusually high number of pseudogenes for a homeobox gene and must reflect expression in the human germ line. A pseudogene orthologous to NANOGP4 was found in chimpanzee and an expressed pseudogene in macaque. Examining pseudogenes of differing ages gives insight into pseudogene decay, which involves an excess of deletion mutations over insertions. The mouse genome has two processed pseudogenes, which are not clear orthologues of the primate pseudogenes.     

Pseudogene IFN-alpha L: removal of the stop codon in the signal sequence permits expression of active human interferon

Biologically active interferon (10(6)-10(7) units/liter) was produced in Escherichia coli from modified human alpha interferon (IFN-alpha) pseudogene L. IFN-alpha pseudogene L has a stop codon in the signal peptide coding region. The region that contains the stop codon was replaced with the corresponding region of another human IFN-alpha gene, WA, that does not have a stop codon and was previously engineered for expression by fusion to the M13mp11 lac promoter. The interferon L fusion product was induced with IPTG after infecting E. coli JM103 with the M13 bacteriophage that contained the modified human IFN-alpha pseudogene L. Hence, the IFN-alpha L mature interferon coding sequence, which is not identical to any other alpha-interferon gene, has been conserved for active interferon coding information.     

Overlapping two genes in human DNA: a salivary amylase gene overlaps with a gamma-actin pseudogene that carries an integrated human endogenous retroviral DNA

The human salivary amylase gene (amy1), consisting of eleven exons, is expressed in the salivary gland and in some amylase-producing tumors. Its uppermost exon and the following intron, along with the 5'-flanking region of this gene, are shown to be superimposed with a gamma-actin pseudogene sequence, a portion of which is transcribed into salivary amylase mRNA and another portion of which serves as a promoter for the amy1 gene. In the further upstream region, the gamma-actin pseudogene sequence is interrupted by a human endogenous retroviral nucleotide sequence.     

Novel use of a chimpanzee pseudogene for chromosomal mapping of human cytochrome c oxidase subunit IV

We have isolated a chimpanzee processed pseudogene for subunit IV of cytochrome c oxidase (COX; EC 1.9.3.1) by screening a chimpanzee genomic library in lambda Charon 32 with a bovine liver cDNA encoding COX subunit IV (COX IV), and localized it to a 1.9-kb HindIII fragment. Southern-blot analysis of genomic DNA from five primates showed that DNAs from human, gorilla, and chimpanzee each contained the 1.9-kb pseudogene fragment, whereas orangutan and pigtail macaque monkey DNA did not. This result clearly indicates that the pseudogene arose before the divergence of the chimpanzee and gorilla from the primate lineage. By screening Chinese hamster x human hybrid panels with the human COX4 cDNA, we have mapped COX4 genes to two human chromosomes, 14 and 16. The 1.9-kb HindIII fragment containing the pseudogene, COX4P1, can be assigned to chromosome 14, and by means of rearranged chromosomes in somatic cell hybrids, to 14q21-qter. Similarly, the functional gene, COX4, has been mapped to 16q22-qter.